EP4162823A1 - Inhaler - Google Patents

Abstract

The invention relates to an inhaler component for the intermittent formation of a vapour-air mixture and/or condensation aerosol, synchronous with inhalation or puff, comprising: a housing (3); a chamber (21) arranged in the housing (3); an air inlet port (26) for admitting air from the environment into the chamber (21); an electrical heating element for evaporating a portion of a liquid material (16), the vapor formed mixing in the chamber (21) with the air supplied through the air inlet opening (26) and forming the vapour-air mixture and/or condensation aerosol ; and a wick with a capillary structure, which wick forms a composite (22) with the heating element and automatically supplies the heating element again with the liquid material (16) after evaporation. In order to be able to achieve the high specific evaporation capacity required for intermittent, inhalation-synchronous or puff-synchronous operation of the inhaler component (2) while at the same time having a high degree of evaporator efficiency, it is proposed that the composite (22) be of flat design and at least one heated section of the composite (22 ) without contact in the chamber (21) and to largely expose the capillary structure of the wick in said section at least on one side (24) of the planar composite.

Description

• ein Gehäuse;
• eine im Gehäuse angeordnete Kammer;
• eine Lufteinlaßöffnung für die Zufuhr von Luft aus der Umgebung in die Kammer;
• ein elektrisches Heizelement zur Verdampfung einer Portion eines flüssigen Materials, wobei der gebildete Dampf sich in der Kammer mit der durch die Lufteinlaßöffnung zugeführten Luft mischt, und sich das Dampf-Luft-Gemisch oder/und Kondensationsaerosol bildet;
• und einen Docht mit einer Kapillarstruktur, welcher Docht mit dem Heizelement einen Verbund bildet und das Heizelement nach einer Verdampfung von neuem selbsttätig mit dem flüssigen Material versorgt.

The invention relates to an inhaler component for the intermittent formation of a vapour-air mixture and/or condensation aerosol, synchronous with inhalation or puffing, comprising:

• a housing;
• a chamber disposed in the housing;
• an air inlet port for admitting air from the environment into the chamber;
• an electrical heating element for evaporating a portion of a liquid material, the vapor formed mixing in the chamber with the air supplied through the air inlet opening, and forming the vapour-air mixture and/or condensation aerosol;
• and a wick having a capillary structure, which wick forms a composite with the heating element and automatically supplies the heating element again with the liquid material after evaporation.

The invention relates to inhalers which allow intermittent, inhalation-synchronous or puff-synchronous operation. One such mode of operation is when the liquid material is heated and vaporized only during a puff or during an inhalation. In intervals between two puffs or inhalations, the heating element is largely deactivated. The heating element is usually activated or energized right at the beginning of a puff or an inhalation, either manually, for example by means of a switch, but preferably automatically via a suitable sensor and an electronic circuit. In the latter case one also speaks of an inhalation or draw-activated operation of the inhaler.

In the present patent application, the term "inhaler" refers to medicinal as well as non-medicinal inhalers. The term also refers to inhalers for administering drugs and substances that are not declared as drugs. The term also refers to Smoking articles and cigarette substitute articles, such as those contained in European patent class A24F47/00B, insofar as these are intended to provide the user with a vapor/air mixture and/or condensation aerosol. The term "inhaler" is also not intended to make any restrictions as to how the vapour-air mixture formed and/or condensation aerosol is supplied to the user or his body. The vapour-air mixture and/or condensation aerosol can be inhaled into the lungs, or just fed into the oral cavity - without inhaling into the lungs. Finally, the term "inhaler" includes both devices that allow direct lung inhalation in a single step ("classic inhalers") and devices that - like a cigarette - require at least two steps, namely a puff first into the oral cavity (puff volume: approx. 20-80mL) and - after stopping the inhaler - a subsequent lung inhalation ("puff inhalers"). Classic inhalers have a significantly higher air flow through the inhaler compared to draw inhalers: approx. 100-750mL/s compared to 10-40mL/s. In contrast, draw inhalers generally have a significantly higher flow resistance or draw resistance than classic inhalers.

• Verdampfungsenergie: Sensible plus latente Wärmemenge, welche auf das tatsächlich verdampfende flüssige Material übertragen wird.
• Verdampfungsleistung: pro Zeiteinheit umgesetzte Verdampfungsenergie.
• Spezifische Verdampfungsleistung: auf die Masseneinheit des verdampfenden, flüssigen Materials bezogene Verdampfungsleistung.
• Verdampfer-Wirkungsgrad: Quotient aus Verdampfungsenergie und vom Heizelement erzeugte Energie.

Definition of terms:

• Vaporization Energy: Sensible plus latent amount of heat transferred to the actual vaporizing liquid material.
• Evaporation capacity: Evaporation energy converted per unit of time.
• Specific evaporation capacity: evaporation capacity related to the unit mass of the evaporating liquid material.
• Evaporator efficiency: quotient of evaporation energy and energy generated by the heating element.

A variety of inhalers and electric smoking articles have been proposed over the years which utilize electrical energy to vaporize drugs and/or flavorings and optionally provide the generated vapor and/or condensation aerosol to a user for inhalation.

GB 25,575 A.D.1911 (Elwin Kendal Hill) describes an inhaler with an electric vaporizer for vaporizing medicaments. The evaporator consists of a disk 38 and a perforated cover 39. In the space between the disk 38 and the cover 39 are on the one hand an absorption material 40 absorbing the drug and on the other hand an electrical heating element 41 - for example in the form of a resistance heating wire. The liquid medicament is automatically supplied to the absorption material 40 or heating element 41 via a corresponding number of wicks 45 from a reservoir 30 . The air sucked in during inhalation flows through a cone-shaped channel 36, whereby the air flow is focused onto the vaporizer and in this way picks up the vaporized drug. The evaporator disc 38 is held in place by spacer sleeves 44 .

The main disadvantage of this arrangement is the complicated structure of the evaporator, its holder and the connection of the wick to the evaporator. The multi-part and complex structure of this design makes the inhaler expensive to manufacture and cumbersome to assemble.

A serious disadvantage can be seen in the fact that the ratio of the vapor outlet surface to the evaporator volume is relatively small. On the one hand, this is due to the specific geometry of the evaporator and, on the other hand, it is due to the fact that the absorption material 40 and the electrical heating element 41 are largely covered by the disc 38 and the cover 39. These covers are required for design reasons in order to absorb the absorption material 40 and to hold the electric heating element 41 together. The vapor formed inside the evaporator can only escape through the holes in the cover 39. As a result, a boiling crisis can occur even with a comparatively moderate evaporation capacity in the evaporator, which is why this arrangement for intermittent, inhalation-synchronous or draw-synchronous operation, which basically has a higher specific Evaporation performance with a simultaneously high evaporator efficiency requires appears unsuitable.

Another disadvantage is that, despite the precautions taken to prevent liquid medication from escaping from the reservoir 30, such an exit cannot be completely ruled out due to the design, particularly if the reservoir 30 is overfilled, e.g. due to incorrect operation. Finally, it must be assessed critically that the liquid drug in the reservoir 30 is exposed practically freely to the ambient air, which can lead to the drug oxidizing and/or to a change in its composition due to evaporation effects.

US 2,057,353 (Clinton L. Whittemore ) describes an evaporator unit for a therapeutic apparatus, consisting of a vessel A for holding a liquid drug x, electrical conductors 1 and 2 protruding through the vessel bottom into the vessel, a heating wire 3, which is connected to the electrical conductors, and a wick D , which is wrapped by the heating wire 3 and extends from this to the bottom of the vessel. The jar has an air inlet port 4 and a vapor outlet port 5, both of which are concave inward to prevent the medicament from escaping the jar.

A disadvantage of this construction is the complex manufacturing process for the connection between the heating element and the wick. The wick must be wrapped with the heating wire before assembly. This procedure is particularly complex because the parts to be joined are usually extremely small. In addition, it is difficult to ensure that the filament windings are all in contact with the wick. Local detachments can lead to overheating of the heating wire in these areas and cause the resistance material to age more quickly. This problem also affects the areas where the heating wire is connected to the electrical conductors 1 and 2.

Another disadvantage is that the outer surface of the wick D is partially covered by the heating element 3 wrapping. In this respect, the wrapping represents an obstacle to the steam escaping from the wick. This hindrance to the flow of steam can have consequences similar to those already explained in more detail above for document GB 25,575 AD1911. In addition, the vapor formed comes at least partially with the outflow hot heating wire in contact, which can lead to thermal decomposition of the drug x.

Another disadvantage is that the wick D is held in position only by the relatively thin heating wire 3 . Even a shock could change the position of the wick D and significantly change the flow and mixing ratios between the air sucked in through the opening 4 and the vapor flowing out of the wick D and impair the formation of aerosols. The apparatus can only be operated in an upright or slightly inclined position; an escape of the medicament x from the vessel A cannot be entirely ruled out despite the design measures taken. Finally, the medicament x in the container A is practically freely exposed to the ambient air, a circumstance which must also be regarded as very unfavourable.

FR 960,469 (M. Eugene Vacheron ) describes an inhaler with an electric vaporizer. The inhaler comprises an electric heating cartridge 4, 5, 6 and a wick 16, which wick is impregnated with the liquid stored in the container 1. The heating cartridge is located outside of the container 1, so it is not directly connected to the wick. The special structural conditions make the inhaler thermally inert and make it seem suitable at best for continuous evaporator operation; an intermittent, inhalation or train synchronous operation does not seem feasible.

CA 2,309,376 (Matsuyama Futoshi ) describes a vaporizer or nebulizer for medical applications, consisting of ( 3 ) a vessel 1 containing a liquid formulation and a rod-shaped porous material 3 installed in the vessel 1. The rod-shaped porous material 3 has one end immersed in the liquid formulation while the other end freely extends outside the vessel 1 extends above. The vessel 1 and the rod-shaped porous material 3 are placed in a domed container 5 . The domed container 5 on the one hand holds the vessel 1 in position and on the other hand contains an electric heater 6 which encases the rod-shaped, porous material 3 in an upper end section at a distance, the distance preferably being in the range 0.8-2.5 mm. The capillary forces in the rod-shaped, porous material 3 cause the liquid formulation is sucked upwards, where the formulation finally from of the electric heater 6 is vaporized. The active substances contained in the liquid formulation are thereby atomized and pass through the opening 9 out of the curved container 5 into the room, so that they can be inhaled by the user. The liquid formulation consists of an aqueous solution in which an active ingredient concentrate is dissolved or dispersed. The aqueous solution preferably consists of water or a mixture of water and ethanol. The active ingredient concentrate is obtained from the leaves of Lagerstroemia Speciosa and contains up to 15% by mass of corosolic acid. The active ingredient concentrate is said to have a blood sugar-lowering effect. The proportion of active ingredient concentrate (calculated as corosol acid) in the aqueous solution is 0.5-3.0% by mass.

The evaporator is designed for continuous operation. The electrical heating device 6 is arranged at a distance from the porous material 3 and consequently does not form a composite with it. The gap between them represents a high heat conduction resistance. Intermittent operation with a correspondingly high specific evaporation capacity would only be possible if the heat were transferred by thermal radiation. For this purpose, the electrical heating device 6 would have to be heated up to a very high temperature in a flash. The liquid formulation would primarily evaporate in the edge zone facing the heating device and flow through the aforementioned gap into the environment. Irrespective of the practical feasibility of this concept, the vapor formed would in any case come into contact with the glowing surface of the heating device 6, as a result of which the active substance concentrate would at least partially be thermally decomposed.

US 6,155,268 (Manabu Takeuchi ) describes an aroma-generating device consisting of ( 1 ) a chamber 121 with an air inlet 18 and a mouthpiece opening 22 or mouthpiece 16, whereby a gas passage channel 20 is formed, and further comprises a liquid container 32 for receiving a liquid flavoring agent 34, and finally a capillary tube 36 with a first end portion which in the Liquid immersed in the container 32 and a second end portion which communicates with the gas passage channel 20 and further comprises a heating element 42. The liquid flavoring substance 34 flows through the capillary forces acting in the capillary tube 36 to the heating element 42, where it evaporates and as a stream of vapor from the opening 36b into the gas passage duct 20 emanates. The air flow entering the chamber 121 from the outside through the air inlet 18 is focused through the pinhole diaphragm 24, 24a onto the capillary opening 36b, whereby favorable conditions are to be created for an intimate mixture between vapor and sucked-in air or for the formation of an aerosol.

In alternative versions ( Figures 8-13 ) plate-shaped heating elements are proposed. In further exemplary embodiments ( 14 and 15 ) the capillary tube is internally filled with a pore structure 302, which in a variant can also protrude from the capillary tube, in which latter case the heating element 425 can be arranged at the end of the protruding pore structure.

The disadvantage of these arrangements is again the relatively complicated structure of the evaporator unit - in this case consisting of the capillary tube and the heating element. These two microcomponents have to be connected to each other and the heating element has to be connected to the electrical supply, which in this specific case can probably only be achieved using electrical wires. Unfortunately, the Scripture does not provide any more precise information in this regard.

For the orders after 14 and 15 The same applies as was already stated for GB 25.575 AD1911: the ratio of the vapor outlet surface to the evaporator volume is extremely small. This is due to the fact that the pore structure 302 is largely covered by the casing 301 and the heating element 425 . As a result, a boiling crisis can occur even with a moderate evaporation rate, which is why the function of these arrangements is fundamentally questionable, especially if intermittent, inhalation-synchronous or draft-synchronous operation is required.

Two variants are proposed for the liquid container 32: in a first variant ( 1 ) the liquid container is a fixed part of the aroma-generating device. The liquid container can be refilled via a filling opening. However, such a refill involves risks for the environment, especially when the liquid flavoring contains drugs or poisons such as nicotine, and the refill is carried out by the user himself. In an alternative variant ( 8 ) is the Liquid container designed as a small interchangeable container. Details about the coupling were not disclosed. Small interchangeable containers always pose a risk of choking by young children, which can be potentially lethal, particularly when the liquid flavoring contains drugs or toxins such as nicotine.

The arrangement after 8 16 also shows an exchangeable mouthpiece 161 with a hollow-cylindrical extension, which lines a large part of the chamber 121 and extends almost to the mouth of the capillary 371. Condensate residues occurring in the chamber 121 are primarily deposited on the inner surface of the hollow-cylindrical extension and can be removed together with the mouthpiece. The problem is that the inner surface can only absorb condensate to a limited extent. The mouthpiece must be changed at frequent intervals, especially if the liquid flavoring substance contains large proportions of low-boiling fractions with high vapor pressure - eg ethanol and/or water. Otherwise, drops form on the inner surface of the mouthpiece under the influence of surface tensions, and these droplets steadily increase in volume until the adhesive forces are finally no longer sufficient to hold the droplets, and they combine to form larger accumulations of liquid. These accumulations of liquid can impair the functioning of the device, but can also pose a risk to the user and the environment if these accumulations contain drug residues or toxins such as nicotine. But even the possibility of having the condensate removed from the device by the user himself harbors a risk for the environment.

U.S. 4,922,901 , U.S. 4,947,874 and US 4,947,875 (Johnny L Brooks et al. ) describe articles for the delivery of drugs and/or flavors with a replaceable unit 12 which contains an electrical resistance heating element 18, the surface area of which is greater than at least 1m^2/g; the electrical resistance heating element 18 carries aerosol forming substances. Preferably, the electrical resistance heating element 18 consists of a porous or fibrous material - for example carbon fibers, which material is impregnated with a liquid aerosol former. The articles also include a puff-activated electronic control unit 14 for controlling the current through the electrical resistance heating element 18 and are capable of delivering at least 0.8 mg of aerosol or drug per puff, wherein a total of at least 10 trains are made possible before the replaceable unit 12 including the resistance heating element 18 must be replaced with a new one.

In this article, the entire liquid material to be evaporated is already pre-stored in the resistance heating element 18 . A liquid supply via a wick is not provided. This also results in the disadvantages: the aerosol-forming substances or the drug and/or any added aroma substances, which are released, for example, during the last puff, have already been heated up many times beforehand, which circumstance favors thermal decomposition of the aerosol-forming substances. This previous heating is also unfavorable in that additional electrical energy is required for this, which makes no contribution to the actual evaporation or aerosol formation. This results in a very low evaporator efficiency. Another disadvantage is that in the case of mixtures of different aerosol-forming substances, drugs and flavorings with different boiling points of the individual substances, the chemical composition of the aerosol formed and its organoleptic and pharmacological effect varies from one inhalation to the next, with low-boiling fractions increasing during the first puffs are vaporized, and higher-boiling substances are increasingly released during the last few puffs. Finally, the replaceable unit 12, which is relatively complex to manufacture, and thus also the heating element 18, must be replaced after about 10 draws, which makes the use of these articles expensive.

U.S. 5,060,671 and US 5,095,921 (Mary E. Counts, D. Bruce Losee et al. ) describe an Article 30 ( 4 ) in which a flavor-releasing medium 111 is heated by electrical heating elements 110 to present inhalable flavors in vapor or aerosol form. The article includes multiple charges of flavor-releasing medium 111 which are sequentially heated to provide single puffs. The multiple charges of the aroma-releasing medium 111 are preferably applied to the heating elements 110 as a covering, coating or as a thin film and can also contain aerosol-forming substances. The adhesion of the aroma-releasing medium 111 to the heating elements 110 can be improved by an adhesion-promoting agent such as pectin. The electrical heating elements 110 and the charges applied to them Flavor-releasing medium 111 are preferably arranged in an exchangeable unit 11, which is connected to a reusable unit 31 via electrical contact pins. The reusable unit 31 contains an electrical energy source 121 and an electronic control circuit 32. US 5,322,075 (Seetharama C. Deevi et al. ) describes a similar article.

Although this article shares some of the disadvantages of the previously described articles ( U.S. 4,922,901 , U.S. 4,947,874 and U.S. 4,947,875 ) fixes, the construction of the replaceable unit 11 appears even more complex, since in the specific case a large number of heating elements including electrical contacting is provided. Furthermore, considering that the complex interchangeable unit 11 allows for little more than 15 puffs (see Figs. 7A-7K), it is clear that such an article would be expensive to use. Furthermore, in the specific case, the aroma-releasing medium 111 is present as a relatively large, thin layer, which is exposed to various environmental influences (oxidation, etc.) primarily during storage of the replaceable unit 11 . In order to avert these influences, expensive packaging would have to be provided, which protects the medium 111 from the environment but does not touch it if possible. Go to that aspect U.S. 5,060,671 and U.S. 5,095,921 not a.

US 2005/0268911 (Steven D. Cross et al. ) is after the previously described article U.S. 5,060,671 and U.S. 5,095,921 very similar and describes a device for generating and dispensing multiple doses of a condensation aerosol for the inhalation of high purity medicaments and consists in the simplest case (Fig. 1A) of an air duct 10 with an inlet and an outlet, a plurality of carriers 28 arranged in the air duct, each carrying a specific dose of substance/drug and means for vaporizing these discrete doses. The airflow entering through the inlet is directed to the supports 28 where the condensation aerosol is ultimately formed. The carriers 28 each contain an electrical resistance heating element - preferably consisting of a metal foil 78 made of stainless steel. The metal foil heating elements 78 are preferably mounted on a circuit board ( 4 ). The cons of the article after U.S. 5,060,671 and U.S. 5,095,921 apply equally to the device US2005/0268911 .

U.S. 5,505,214 and US 5,865,185 (Alfred L. Collins et al. ) describe electric smoking articles consisting of ( 4 ; U.S. 5,505,214 ) an exchangeable unit 21 and a reusable part 20. The exchangeable unit 21 contains tobacco flavors 27, which are located on a carrier 36. The reusable part 20 contains a plurality of heating elements 23 which are supplied with power or energy via an electrical control circuit from an electrical energy source--for example a rechargeable battery. After the exchangeable unit 21 has been inserted into the reusable part 20 , the carrier 36 comes to rest on the heating elements 23 . During an inhalation or a puff, an individual heating element is activated by the control circuit, as a result of which the carrier 36 is heated in sections and the tobacco aromas 27 are vaporized and optionally released as an aerosol. In the embodiment after 4 the reusable part 20 contains eight heating elements 23, after which eight inhalations or puffs are permitted, similar to a cigarette. Thereafter, the replaceable unit 21 is to be replaced with a new unit.

Opposite the article after U.S. 5,060,671 and U.S. 5,095,921 indicate the smoking articles U.S. 5,505,214 and U.S. 5,865,185 has the advantage that the heating elements 23 are arranged in a stationary manner in the reusable part 20 and can thus be used repeatedly. Electrical contacts between the replaceable unit 21 and the reusable part 20 are not required. Disadvantageous compared to the article noisy U.S. 5,060,671 and U.S. 5,095,921 is, however, that in addition to the heating elements 23, the carrier 36 must also be heated; the heat required for this degrades the evaporator efficiency. The other disadvantages of the article mentioned earlier according to U.S. 5,060,671 and U.S. 5,095,921 apply accordingly.

US 4,735,217 (Donald L. Gerth et al. ) describes a dosing unit for administering vaporized medication in the form of fine aerosol particles, which are inhaled into the lungs. The dosing unit consists of an exemplary embodiment ( 4 and 5 ) of a Nichrome ^® foil-type heating element segment 72 (length x width x thickness: 1 x 1/8 x 0.001 inch) connected in series with a battery 65 and an airflow or draft activated switch (60,69). The drug to be vaporized - for example nicotine - is present as a solid pellet 40, which Heating element 72 contacted. Alternatively, the medicament to be vaporized can be applied directly to the heating element surface in the form of a coating or film.

Some of the disadvantages of this dosing unit have already been mentioned in U.S. 4,922,901 mentioned. In addition, the heat transfer from the heating element to the pellet is very unfavourable. A large part of the heating element 72 is heated up without benefit, since the heat generated in the peripheral areas of the heating element can only be used to a small extent for the pellet. A fundamental disadvantage is that solids are needed to form the pellets, which generally first have to be melted before they can be evaporated, which further worsens the energy balance.

EP 1,736,065 (Hon Lik ) describes an “electronic cigarette” for atomizing a nicotine solution and essentially consists of a container 11 for holding the liquid to be atomized and an atomizer 9. Inside the atomizer 9 is an atomizer chamber 10, which is formed by the atomizer chamber wall 25. An electrical heating element 26, for example in the form of a resistance heating wire or a PTC ceramic, is arranged inside the atomizing chamber 10. Ejection holes 24 , 30 are also provided in the atomizer or in the atomizer wall 25 and point in the direction of the heating element 26 . The container 11 includes a porous body 28 - for example consisting of plastic fibers or foam, which is impregnated with the liquid to be atomized. The atomizing chamber wall 25 is also surrounded by a porous body 27--consisting, for example, of nickel foam or a metal felt. The porous body 27 is in contact with the porous body 28 via a bulge 36 . Capillary forces cause the porous body 27, which at the same time forms the outer shell of the atomizer 9, to be infiltrated with the liquid to be atomized. The atomizer also includes a piezoelectric element 23.

The "electronic cigarette" is operated by pulling. During a puff, a vacuum is created in the atomizer chamber 10 because it is connected to the mouthpiece 15. As a result, air flows from the environment via the ejection holes 24, 30 into the atomizer chamber. The high flow speed in the ejection holes 24, 30 causes liquid to be sucked out of the porous body 27 and from the air flow in the form of drops is entrained (Venturi effect). The nicotine-containing liquid enters the atomizer chamber 10, where it is atomized by means of the piezoelectric element 23 by ultrasound. The heating element 26 is intended to bring about additional atomization or vaporization of the nicotine solution. In an alternative embodiment variant, the atomization takes place exclusively through the heating element 26.

The arrangement shows functional similarities with the in US 4,848,374 (Brian C. Chard et al. ) disclosed smoking device. In both cases, it is disadvantageous that the dosage of the liquid to be atomized or of the aerosol formed depends on the respective puff profile of the user, similar to that of a cigarette. However, this is undesirable in medical or therapeutic applications. In addition, atomization by means of ultrasound generally produces significantly larger aerosol particles than condensation aerosols usually have. These larger particle fractions do not reach the alveoli, but rather are already absorbed in the upstream lung sections, which in the case of systemically acting drugs such as nicotine has a very unfavorable effect on the absorption kinetics and the efficiency of drug delivery. Furthermore, particularly in the case of the alternative embodiment variant without ultrasonic atomization, it must be doubted whether the electric heating element, which is designed like a light bulb wire, is at all capable of transferring the heating energy required for evaporation during one puff to the liquid material. This would probably only be possible through heat radiation, for which the heating element would have to be brought to the proverbially glowing temperature. Such high temperatures are fundamentally associated with various dangers and disadvantages - including the risk of thermal decomposition of the liquid to be atomized or already atomized. Finally, the fact that the container containing the very toxic nicotine solution is open at one end and can also be detached from the "electric cigarette" must be regarded as a high safety risk. This risk has already been recognized and was addressed in a further training course - as in DE 202006013439U disclosed - partially mitigated insofar as the container is formed by a hermetically sealed cartridge, which cartridge, however, still has the disadvantage of being detachable from the "electric cigarette" and can, for example, be swallowed by small children.

Finally, it should be noted that some of the documents just presented, although they do not belong to the type of invention described at the outset, were nevertheless described because they at least reflect the further state of the art and are therefore worthy of being considered.

The invention is based on the object of eliminating the disadvantages of the arrangements known from the prior art, which have been indicated above. The invention is based in particular on the object of designing an inhaler component of the type described at the outset in such a way that the high specific vaporization capacity required for intermittent, inhalation-synchronous or puff-synchronous operation can be realized with a simultaneously high vaporizer efficiency. The necessary power and energy requirements should be covered by an energy storage device roughly the size of an average mobile phone battery. The occurrence of a boiling crisis in the wick should be avoided, and the liquid material should be able to be vaporized as gently as possible, ie without significant thermal decomposition.

The inhaler component should also allow user-friendly and safe operation and be able to be manufactured as inexpensively as possible, which means in concrete terms: The composite should be infiltrated by the liquid material as quickly as possible, so that no significant waiting times have to be observed between two inhalations or puffs. The inhaler component should be able to be operated in any position. The risk of liquid material - including liquid condensate residues - entering the environment or impairing the function of the inhaler component should be minimised. The composite should be able to be produced as inexpensively as possible. The inhaler component should be designed to be handy and ergonomic and easy to use.

Furthermore, the properties of the vapor-air mixture formed and/or condensation aerosol should be able to be influenced at least within certain limits—above all the particle size distribution of the condensation aerosol formed and the organoleptic effects of the same.

Finally, the inhaler component should be designed in two fundamentally different variants, so that it can be used both in classic inhalers and in inhalers.

The object is achieved in that the composite is flat and at least one heated section of the composite is arranged without contact in the chamber and the capillary structure of the wick in said section is largely exposed on at least one side of the flat composite. In a development of the invention, the capillary structure of the wick is largely exposed in said section on both sides of the planar composite. Due to the fact that the capillary structure of the wick is largely exposed in said section, the vapor formed can flow out of the wick unhindered, whereby the evaporation capacity can be increased or a boiling crisis in the wick can be avoided.

• "Flächiger Verbund" bedeutet, daß das Heizelement und der Docht in derselben Fläche oder/und in zueinander parallellen Flächen angeordnet und miteinander verbunden sind. Der kapillare Transport des flüssigen Materials im flächigen Verbund erfolgt primär in Flächenrichtung.
• "Berührungsfrei" bedeutet, daß weder die Kammerwand noch sonstige Strukturelemente der Inhalatorkomponente berührt werden; durch die berührungsfreie Anordnung in der Kammer wird erreicht, daß die Wärmeleitungsverluste des Verbundes in diesem Abschnitt wesentlich herabgesetzt werden, und der Verbund soweit erhitzt wird, daß das im Docht gespeicherte flüssige Material verdampfen kann.
• "Kammer" soll auch Kanäle mit einschließen; somit fällt auch ein rohrförmiger Kanal unter den Begriff "Kammer"; ein offenes Rohrende könnte in diesem Fall beispielsweise die Lufteinlaßöffnung bilden.

Explanation of terms:

• "Flat composite" means that the heating element and the wick are arranged and connected to one another in the same area or/and in areas parallel to one another. The capillary transport of the liquid material in the two-dimensional composite takes place primarily in the direction of the surface.
• "Non-contact" means that neither the chamber wall nor other structural elements of the inhaler component are touched; the contact-free arrangement in the chamber means that the thermal conduction losses of the composite are significantly reduced in this section, and the composite is heated to such an extent that the liquid material stored in the wick can evaporate.
• "Chamber" is also intended to include channels; thus also a tubular channel falls under the term "chamber"; in this case, for example, an open pipe end could form the air inlet opening.

In a preferred embodiment, the planar composite has a thickness of less than 0.6 mm, and in a particularly preferred embodiment a thickness of less than 0.3 mm. The result of this dimensioning is that the heat introduced over the surface can flow efficiently by thermal conduction--ie, with a small temperature gradient--to the exposed wick surface or capillary structure, where it causes the liquid material to evaporate. Already inside the wick vapor formed can also more easily reach the exposed wick surface. These conditions enable a further increase in the evaporation capacity and contribute to the liquid material being evaporated particularly gently. It should be noted that this is not just a simple dimensioning, but an essential feature of the invention. Even the inventor was surprised when he found in experiments that flat wicks with an exposed wick surface and a thickness of <300 μm still show a wicking effect in the flat direction.

It is considered to be according to the invention that the composite is plate-shaped, film-shaped, strip-shaped or band-shaped. These two-dimensional arrangements make it possible to use manufacturing processes that allow particularly economical mass production.

According to the invention, the planar composite contains one of the following structures: fabric, open-pored fiber structure, open-pored sintered structure, open-pored foam, open-pored deposition structure. These structures are particularly suitable for producing a wick body with a high porosity. A high porosity ensures that the heat generated by the heating element is largely used for evaporating the liquid material located in the pores, and a high degree of evaporator efficiency can be achieved. Specifically, a porosity greater than 50% can be realized with these structures. The open-pored fiber structure can consist, for example, of a fleece that can be compacted as desired and additionally sintered to improve cohesion. The open-pored sintered structure can consist, for example, of a granular, fibrous or flaky sintered composite produced by a film casting process. The open-pored deposition structure can be produced, for example, by a CVD method, PVD method, or by flame spraying. Open-pored foams are generally commercially available and are also available in a thin, fine-pored version.

In one embodiment of the invention, the planar composite has at least two layers, the layers containing at least one of the following structures: plate, film, paper, fabric, open-pored fiber structure, open-pored sintered structure, open-pored foam, open-pored deposition structure. Certain layers can be assigned to the heating element and other layers to the wick. For example, the heating element are formed by an electrical heating resistor consisting of a metal foil. However, it is also possible for one layer to assume both heating element and wick functions; such a layer can consist of a metal wire mesh which, on the one hand, contributes to the heating due to its electrical resistance and, on the other hand, exerts a capillary effect on the liquid material. The individual layers are advantageously, but not necessarily, connected to one another by a heat treatment such as sintering or welding. For example, the composite can be designed as a sintered composite consisting of a high-grade steel foil and one or more layers of a high-grade steel wire mesh (material such as AISI 304 or AISI 316). Instead of high-grade steel, heating conductor alloys--in particular NiCr alloys and CrFeAl alloys ("Kanthal")--can be used, for example, which have an even higher specific electrical resistance than high-grade steel. The heat treatment creates a material connection between the layers, which means that the layers remain in contact with each other - even under adverse conditions, for example during heating by the heating element and the thermal expansion induced by it. If the contact between the layers were lost, a gap could form, which on the one hand could disturb the capillary coupling and on the other hand the heat transfer from the heating element to the liquid material.

In an analogous embodiment of the invention, it is provided that the composite is linear and at least one heated section of the composite is arranged without contact in the chamber and the capillary structure of the wick is largely exposed in said section. Due to the fact that the capillary structure of the wick is exposed in said section, the vapor formed can flow out of the wick unhindered, as a result of which the evaporation capacity can be increased or a boiling crisis in the wick can be avoided. The capillary transport of the liquid material in the linear assembly takes place primarily in the longitudinal direction of the linear assembly. The terms "non-contact" and "chamber" have been explained earlier.

(A bezeichnet die Querschnittsfläche des Verbundes). Diese Dimensionierung hat zur Folge, daß die linienförmig eingebrachte Wärme durch Wärmeleitung effizient - d.h. bei kleinem Temperaturgradienten der freiliegenden Dochtoberfläche zufließen kann, wo sie die Verdampfung des flüssigen Materials bewirkt. Bereits im Inneren des Dochts gebildeter Dampf kann außerdem leichter die freiliegende Dochtoberfläche erreichen. Diese Bedingungen ermöglichen eine weitere Steigerung der Verdampfungsleistung.The linear composite preferably has a thickness of less than 1.0 mm, the thickness being defined by: $\sqrt{4*A/\pi }$

(A denotes the cross-sectional area of the composite). This dimensioning has the consequence that the line-shaped introduced heat efficiently through heat conduction - ie with small Temperature gradients can flow to the exposed wick surface where it causes vaporization of the liquid material. Vapor already formed inside the wick can also more easily reach the exposed wick surface. These conditions allow a further increase in the evaporation capacity.

According to the invention, the linear composite contains at least one of the following structures: wire, yarn, open-pore sinter structure, open-pore foam, open-pore deposition structure. These structures are particularly suitable for producing a linear composite with sufficient mechanical stability and high porosity.

In a preferred embodiment of the planar or linear composite, the heating element is at least partially integrated into the wick. This arrangement has the advantageous effect that the heat is generated and released directly in the wick body, where it is directly transferred to the liquid material to be vaporized. For example, the heating element can consist of an electrically conductive thin layer of platinum, nickel, molybdenum, tungsten, tantalum, which thin layer is applied to the wick surface by a PVD or CVD process. In this case, the wick consists of an electrically non-conductive material - for example quartz glass. In an embodiment of the invention that is simpler in terms of production technology, the wick itself consists at least partially of an electrical resistance material, for example carbon, of an electrically conductive or semiconductive ceramic or of a PTC material. It is particularly favorable when the electrical resistance material is metallic. Compared to the materials mentioned above, metals have a higher ductility. This property proves to be advantageous insofar as the composite is exposed to thermal cycling during operation, which induces thermal expansion. Metals are better able to compensate for such thermal expansions. In addition, metals have a higher impact strength in comparison. This property is found to be an advantage when the inhaler component is subjected to impact. Suitable metallic resistance materials are, for example: stainless steels such as AISI 304 or AISI 316 and heating conductor alloys - in particular NiCr alloys and CrFeAl alloys ("Kanthal") such as DIN material number 2.4658, 2.4867, 2.4869, 2.4872, 1.4843, 1.4860, 1.4725, 1.4765 , 1.4767.

In a further preferred embodiment of the planar or linear composite, it is provided that the connection between the heating element and the wick extends over the entire extent of the wick. It is irrelevant whether the heating element is used as such over its entire extent - i.e. heated, or only in sections. This depends on the respective position of the electrical contact of the heating element. Even if this contact is made at the outer ends of the heating element, the heating element does not necessarily have to contribute to the evaporation of the liquid material over its entire extent. In this way, the heating element can touch structural components in sections, which largely dissipate the heat generated in the heating element, so that the liquid material in the wick is practically not heated, at least in this section. However, this outflowing heat would have to be assessed as a loss in the energy balance. This configuration makes it possible to use production methods which offer significant cost advantages compared to the prior art and make mass production economical in the first place. In this way, the planar composite can be obtained in large numbers from a planar multiple panel by detaching the composite from this multiple panel using suitable separation methods such as stamping or laser cutting. The linear composite can advantageously be obtained from an endless material. The term "endless material" also includes a material with a finite length, provided that this length is many times greater than the length of the linear composite.

As already explained earlier, a high porosity of the wick or of the composite is desirable with regard to an effective use of the thermal energy introduced by the heating element. The porosity can also be increased by etching the composite or its preliminary production stage - e.g. the multiple panel. For example, a sintered composite consisting of a stainless steel foil and one or more layers of stainless steel mesh (e.g. AISI 304, AISI 316) can be treated accordingly in an aqueous pickling bath consisting of 50% nitric acid and 13% hydrofluoric acid, with the electrical resistance of the heating element or Influenced composite, namely can be increased.

According to the invention, the surface of the assembly or its preliminary production stage can also be activated. This measure also includes a cleaning of the surface and causes a better wetting of the composite material by the liquid material and thus a faster infiltration of the wick. For example, a treatment in 20% phosphoric acid is very well suited for the sintered composite mentioned above, consisting of a stainless steel foil and one or more layers of a stainless steel mesh, in order to achieve the aforementioned effects.

In an advantageous embodiment of the invention, the wick is designed as an arterial wick. This type of wick is mainly used in heat pipes and is described in more detail in the relevant literature - see e.g. ISBN 0080419038. Such a wick can, for example, consist of a bundle of channels or capillaries - so-called "arteries" - which are surrounded by a finer pore structure or are formed by this. Compared to a homogeneous pore structure of the same capillarity or the same capillary pressure (capillary rise), the bundle of channels or capillaries offers the liquid material a lower flow resistance, which means that the infiltration of the wick with the liquid material can be significantly accelerated.

In an embodiment variant, the wick is perforated in the direction of thickness. The perforation can be done, for example, by means of a laser and has the following effects: on the one hand, the porosity is further increased; on the other hand, the flow resistance in the thickness direction is reduced. The latter effect is particularly evident when using an arterial wick, inasmuch as the liquid material in the wick experiences an increase in pressure during evaporation and the perforation acts as a pressure relief. This prevents the vapor formed in the wick from forcing the liquid material back through the arteries to the source of the liquid material, which can severely disrupt the supply of liquid material.

It is also considered to be according to the invention that the planar composite is essentially flat and the air inlet opening is designed as a slot-shaped channel and the slot-shaped channel is aligned parallel to the flat composite surface. Analogously, it is considered to be according to the invention that the line-shaped composite is configured essentially in a straight line and the air inlet opening is configured as a slot-shaped channel, and the slot-shaped channel is aligned parallel to the straight-line composite. These geometrically simple arrangements can very favorable mixing conditions between the inflowing air and the vapor exiting the wick are created, which mixing conditions can furthermore be easily varied by changing the position of the slit-shaped channel or/and by changing the slit height; in this way it is possible to influence the properties of the aerosol formed--in particular the size of the aerosol particles formed--to a certain extent.

According to the invention, the composite penetrates the chamber in the manner of a bridge and is supported with two end sections on two electrically conductive, plate-shaped contacts, and the heating element is electrically contacted with the contacts. Considering that the composite is an extremely small and mechanically sensitive component, which is also exposed to the flow forces of the air flowing into the chamber and forces due to thermal expansion, it becomes clear that the arrangement just described is a relatively stable and simple to manufacture Anchoring and contacting of the composite allows. In a preferred embodiment of the invention, the electrical contacting of the heating element consists of a welded or sintered connection. The welded connection can be produced by spot welding, resistance welding, ultrasonic welding, laser welding, bonding or other suitable welding methods. It is particularly favorable for the welding or sintering if the plate-shaped contacts consist of the same or a similar material as the heating element. In another advantageous embodiment of the invention, the electrical contacting of the heating element consists of an adhesive connection using an electrically conductive adhesive, for example using an epoxy-based adhesive containing silver. In this case, the plate-shaped contacts can in principle be made of any electrical contact material, as long as the material is compatible with the adhesive used; alternatively, the plate-shaped contacts can also be formed by printed circuit boards or a common printed circuit board. Thick copper printed circuit boards with a copper layer thickness in the range of 100-500 µm are preferred because of the better heat dissipation. Of course, the invention is not limited to the contacting methods mentioned above. As an alternative, the electrical contact could also be made by mechanical clamping. In a Development of the invention, the plate-shaped contacts protrude from the outer surface of the housing in the form of two plug contacts. The two plug contacts are intended to feed the heating element with the required electrical energy.

In a preferred embodiment of the invention, one end of the composite protrudes into a capillary gap whose flow resistance is less than the flow resistance of the wick. The capillary gap feeds the wick with liquid material; the reduced flow resistance compared to the wick causes the liquid material to reach the evaporation zone in the composite more quickly. However, this also shortens the time required to completely infiltrate the wick again with liquid material after evaporation. This time corresponds to a waiting time, which must be observed at least between two puffs or inhalations. If this waiting time is not adhered to, this can lead to a reduction in the amount of vapor emitted or the drug dose. In addition, because the composite is heated in sections without liquid material, local overheating can occur, which damages the composite or shortens its service life. In a development of the invention, it is provided that the cross section of the capillary gap is larger than the cross section of the composite. This has the effect that the liquid material bypasses the wick in part in the manner of a bypass and in this way reaches the evaporation zone in the composite even more quickly. In a preferred embodiment of the invention, the heating element of the assembly is electrically contacted in the capillary gap. A very space-saving arrangement is thereby achieved.

A preferred embodiment of the invention relates to an inhaler component with a liquid container, which is arranged in the housing or is connected to the housing and contains the liquid material, together with an openable closure; According to the invention it is provided that the liquid container can neither be removed nor separated from the housing, and the liquid material in the liquid container can be capillary coupled to the capillary gap by manually opening the openable closure. The liquid container can therefore not be removed from the inhaler component by the user, even if the liquid material has been used up, which is to be regarded as a safety advantage in particular if the container contains medicines and/or poisons such as nicotine. The housing of the inhaler component is too large for small children to swallow. A refilling of the liquid container is not provided; Rather, the inhaler component together with the liquid container forms a disposable item which is to be properly disposed of after the liquid material has been used up. The liquid material is kept hermetically sealed in the liquid container. Access to air or UV rays is largely excluded. The liquid container can also contain an inert gas such as argon, nitrogen or carbon dioxide, which additionally protects the liquid material from oxidation. The openable closure of the liquid container is expediently only opened shortly before use of the inhaler component, after which the liquid material reaches the wick via the capillary gap and infiltrates it. The openable closure is easily opened manually without the aid of special tools.

In a first embodiment variant, the liquid container is rigidly and permanently connected to the housing, or itself forms part of the housing. The liquid container can be designed, for example, as a separate part which is inseparably connected to the housing by an adhesive bond or a welded connection. In a development of the first embodiment variant, a reservoir communicating with the capillary gap is provided, which is connected to the liquid container and is separated from it by the openable closure. When the closure is open, the reservoir serves to receive at least part of the liquid material from the liquid container and to ensure the capillary coupling with the capillary gap. The openable closure is preferably opened by a pin which is mounted in the housing in an axially displaceable manner, the first end of which is directed towards the openable closure and the second end of which protrudes like an extension from the outer surface of the housing when the closure is closed, by applying a compressive force to the second end of the pin is exercised. The compressive force is transferred from the pin to the openable closure, which finally tears open along a predetermined breaking point. The compressive force can be generated by finger pressure, for example. A particularly favorable embodiment of the invention relates to an inhaler comprising an inhaler component as just described and a reusable one Inhaler part which can be coupled to the inhaler component; according to the invention it is provided that the second end of the pin is in a ram-like operative connection with the reusable inhaler part during the coupling, as a result of which the pressure force described above is generated. The coupling of the inhaler component to the reusable inhaler part and the opening of the liquid container thus take place simultaneously with a single manipulation.

According to the invention, the reservoir communicates with the chamber via a ventilation channel, as a result of which air enters the reservoir and pressure equalization is brought about. In this way, each portion of liquid material that enters the capillary gap is immediately replaced by an equal volume portion of air. It is essential that the ventilation channel is connected to the chamber and not communicates with the outside environment, since otherwise the suction pressure during inhalation would overlay the capillary flow and liquid material would be sucked out of the liquid container according to the straw principle.

In a second embodiment variant, the liquid container is arranged in the housing such that it can be manually displaced along a displacement axis between two stop positions, and the liquid container interacts in the first stop position with a non-unlockable blocking device and in the second stop position with an opening means that opens the openable closure. The blocking device basically prevents the liquid container from being removed from the housing. As in the first embodiment variant, the liquid container cannot be removed from the housing—with the same safety advantages as already described earlier. In a further development of the second embodiment variant, the opening means comprises a first spike formed by the capillary gap, which penetrates the openable closure in the second stop position, as a result of which the capillary coupling with the liquid material is produced. Furthermore, a ventilation channel is again provided, the first end of which communicates with the chamber and the second end of which is designed as a second spike which penetrates the openable closure in the second stop position. The first and the second mandrel thus together form the opening means. The effect of this arrangement is similar to that of a coupling between a fountain pen and its ink cartridge. Of course, the first and the second mandrel also be fused into a single common spike. The blocking device which cannot be unlocked can consist in a simple manner of a projection which is formed, for example, on the housing or on the mouthpiece and against which the liquid container abuts in the first stop position. Finally, the second embodiment variant relates to an inhaler component comprising a mouthpiece with a mouthpiece channel through which a user is presented with the vapour-air mixture and/or condensation aerosol, and according to the invention it is provided that the displacement axis is at least approximately parallel to the central axis of the mouthpiece channel, and the liquid container, at least in the first stop position, protrudes with an end section laterally next to the mouthpiece out of the housing. The slidable liquid container can be easily slid into its second stop position by the user pressing on the protruding end of the liquid container. The mouthpiece and the liquid container protrude from the housing on the same end face of the inhaler component, which makes the inhaler component easy to handle and makes it ergonomic to use.

According to the invention, a buffer store can also be provided, which communicates with the capillary gap and itself consists of capillaries. The buffer reservoir has the ability to absorb liquid material from the capillary gap and, if necessary, release the buffered liquid material to the wick via the capillary gap again, regardless of position. As a result, the inhaler component can be operated in any position, at least as long as liquid material is available in the buffer store. The capillaries can consist, for example, of slits, holes, or of a porous material, it being important to ensure that their capillarity or capillary pressure (capillary rise height) is smaller than the capillarity of the wick, since otherwise no capillary flow occurs.

As an alternative to the liquid container described above, the inhaler component can contain a liquid reservoir made of an elastic, open-pored material and impregnated with the liquid material; According to the invention it is provided that the composite is sandwiched between one of the two plate-shaped contacts - as already described - on the one hand and the liquid reservoir on the other hand is clamped, whereby the wick with the liquid material in the liquid reservoir is capillary is paired. The elastic, open-pored material can consist of a fiber material or foam, for example. The liquid material is automatically sucked out of the liquid reservoir into the wick and infiltrates it. The prerequisite is that the capillarity or the capillary pressure (capillary rise height) of the wick is greater than the capillarity of the liquid reservoir. The sandwich-like clamping represents a structurally simple arrangement that is inexpensive to manufacture.

In a development of the invention, the inhaler component contains a condensate binding device for receiving and storing condensate residues which are formed in the course of generating the vapor-air mixture and/or condensation aerosol; Significant amounts of condensate residues can occur, especially if the liquid material to be evaporated contains large proportions of low-boiling fractions with high vapor pressure, e.g. ethanol and/or water. Such proportions of low-boiling fractions are primarily advantageous for two reasons and also necessary in the case of the inhaler component according to the invention: on the one hand, such proportions reduce the viscosity of the liquid material, as a result of which the liquid material can infiltrate the wick more quickly. This effect proves to be particularly advantageous in the case of the composite according to the invention, since the thickness of the composite and, as a result, also the average pore diameter of the wick are extremely small. On the other hand, the low-boiling fractions cause drugs and other additives contained in the liquid material to evaporate more easily, form fewer evaporation residues and reduce thermal decomposition of the liquid material. In order to utilize these positive effects to a satisfactory extent, the mass fraction of the low-boiling fractions should be well over 50%. Consequently, when the inhaler component according to the invention is in operation, considerable amounts of condensate residues are to be expected, which must be appropriately bound.

According to the invention, the condensate binding device consists of an open-pored, absorbent body which is arranged at a distance from, but in the immediate vicinity of, the capillary structure of the wick that is exposed in said section. The porous, absorbent body absorbs condensate deposits formed from the vapor phase in its pores and in this respect works in a similar way like a sponge. A larger amount of condensate can also be bound without any problems. The open-pored, absorbent body prevents free-flowing accumulations of condensate from forming in the inhaler component, especially in the chamber, which can impair the function of the inhaler component, but also pose a risk to the user and the environment if these accumulations contain drug residues or toxins such as nicotine . Due to the special arrangement of the porous, absorbent body in the immediate vicinity of the vapor formation zone - i.e. in an area of high vapor density - the condensate residues are absorbed in a very high concentration and thus very effectively, and they are not even given the opportunity to scatter peripheral areas. It is particularly favorable if the open-pored, absorbent body directly covers the exposed capillary structure of the wick in said section, since the highest vapor density is to be expected in this zone. In an advantageous embodiment of the invention, the open-pored, absorbent body comprises two parts or sections arranged at a distance from one another, and the composite is arranged at least in sections between the two parts or sections. Furthermore, it is considered according to the invention that the open-pored, absorbent body is arranged in the chamber and fills out the major part of the chamber. In this way, a particularly large absorption capacity for the liquid condensate residues can be realized with a compact design. It is also favorable if the porous, absorbent body consists of a dimensionally stable material which largely retains its shape even after complete infiltration with the condensate residues. In order to determine whether a specific material is dimensionally stable, it is sufficient to soak it in a solution of ethanol and water and check the dimensional stability after three days. The dimensional stability ensures that the flow conditions in the chamber, in particular around the composite, and thus the conditions for the formation of the vapor-air mixture and/or condensation aerosol remain constant. For example, the open-pored, absorbent body can be made of a solid, foam-like material such as metal foam or ceramic foam, of a porous sintered molded body, of a porous filler or bulk material without a tendency to expand, for example of a desiccant granulate bulk, or of a porous fiber composite, for example formed from thermally or with Natural or man-made fibers connected to one another with the aid of a binder. It is also essential that the material is largely chemically inert to the condensate residues.

According to a preferred embodiment of the invention, the porous, absorbent body is largely surrounded by the housing and is inseparably connected to the housing. This is to ensure that the porous, absorbent body cannot come into direct contact with the environment, and removal of the same from the housing is only possible by using force and destroying the inhaler component. This protective measure proves to be particularly advantageous when the condensate contains drug residues and/or poisons such as nicotine. Together with the porous, absorbent body, the inhaler component forms a disposable item that must be properly disposed of after the intended service life has been reached.

In an advantageous development of the invention, a two-stage condensate separating device is provided, consisting firstly of the open-pored, absorbent body and secondly of a cooler through which the vapor-air mixture formed and/or condensation aerosol can flow. This development of the invention is particularly suitable for use in inhalers. The cooler cools the steam-air mixture flowing through and/or condensation aerosol and in doing so extracts further condensate from it. The cooler can be formed, for example, by a porous body that can be flown through and is largely permeable to the particles of the condensation aerosol that is formed. In addition to the cooling, the porous body also causes an intimate mixing of the vapor-air mixture or condensation aerosol flowing through, whereby its properties are homogenized, for example concentration peaks are reduced. The porous body typically consists of a wide-pored material, for example an open-cell foam material, a coarse-pored, porous filling material or a fleece-like fiber material. Synthetic fiber fleeces made of polyolefin fibers (PE, PP) or polyester fibers are mentioned as an example of a fleece-like fiber material. The porous body can also consist of a regenerator material. The regenerator material is able to quickly absorb a lot of heat with a large surface or heat exchange area without significant flow losses. Typical Regenerator materials are: metal wool, metal chips, metal mesh, wire mesh, metal fiber fleece, open-cell metal foams, bulk metal or ceramic granules. Finally, the cooler can also have a multi-stage design by combining different porous materials with one another. Of course, the invention is not limited to the cooler materials listed above. The organoleptic properties of the vapor-air mixture and/or condensation aerosol taken in by the user can be significantly improved by the cooling and homogenization.

In a particularly preferred embodiment of the invention, the cooler is formed by a tobacco filling. In addition to the cooling/condensation and homogenization, the tobacco filling also causes an aromatization of the vapor-air mixture or condensation aerosol flowing through it and is particularly useful if the liquid material contains nicotine as a medicinal product. In laboratory tests with prototypes working according to the inhaler principle and with nicotine-containing medicinal preparations as liquid material, other favorable effects were also found: for example, the inhalability of the nicotine-containing vapor-air mixture and condensation aerosol could be improved, which in part certainly due to the effects described above. However, there is the hypothesis that additional mechanisms of action are involved - in particular diffusion and adsorption processes relating to the free, unprotonated nicotine, which would still have to be researched in detail. The filling density of the tobacco filling is limited by the fact that on the one hand the filling must be as permeable as possible for the aerosol particles flowing through, and on the other hand the induced flow resistance should not be greater than that of cigarettes. The tobacco filling can be formed from cut tobacco, fine-cut tobacco, stuffing tobacco, from a cigar-like tobacco wrapper or from comparable or similar shapes of tobacco. Dried fermented tobacco, reconstituted tobacco, expanded tobacco or mixtures thereof are particularly suitable as tobacco. The tobacco can additionally be flavored, seasoned, flavored and/or perfumed. The use of a tobacco filling as a cooler can also make switching from tobacco products to the inhaler component according to the invention more attractive and/or easier. In a A preferred development of the invention provides that the volume of the tobacco filling is greater than 3 cm3. Our own laboratory tests have shown that the above-mentioned effects of the tobacco filling only come into play to a degree that is satisfactory for the user above the previously specified minimum volume.

According to a further embodiment of the invention, the inhaler component comprises a mouthpiece opening formed by a mouthpiece, which communicates with the chamber and through which a user is presented with the vapour-air mixture and/or condensation aerosol, with the air inlet opening and the mouthpiece opening forms a flow in the direction of the mouthpiece opening, which flow passes through the composite at least in sections. According to the invention, at least one air bypass opening is arranged downstream of the assembly, through which additional air from the environment is fed into the flow, and the effective flow cross section of the air bypass opening is at least 0.5 cm2. This arrangement also makes the inhaler component usable for classic inhalers, which fundamentally require the smallest possible flow resistance. The additional air flowing in through the air bypass opening ("bypass air") does not itself pass through the composite and therefore has no direct influence on the formation of the vapour-air mixture and/or condensation aerosol or on its properties. However, there is an indirect influence in that the bypass air reduces the amount of air flowing in through the air inlet opening ("primary air") if a constant amount of inhalation air is assumed. In this way, the amount of primary air can be reduced as desired. A reduction in the amount of primary air leads to an increase in the aerosol particles formed; at the same time, however, the amount of condensate residues formed also increases, which circumstance can be countered by the arrangement of a condensate binding device - as described above. A further reduction in the flow resistance and a further reduction in the primary air volume are achieved according to the invention by that the air bypass opening consists of two bypass openings, which are arranged in opposite housing sections.

According to the invention, it is also provided that two guide vanes are connected to the two bypass openings, which point in the direction of the mouthpiece opening and strive towards one another, and whose free ends form a nozzle-shaped orifice through which the vapor-air mixture formed and/or condensation aerosol from the Chamber flows out and then mixes with the air flowing in from the bypass openings. The two vanes have the effect that they largely cover the chamber to the outside, which significantly reduces the risk of rainwater or saliva entering the chamber, for example. In addition, the exchange of air between the chamber and the environment is also restricted, thereby reducing the natural evaporation of portions of the liquid material in the wick. Such evaporation can prove disadvantageous, particularly during long periods of non-use of the inhaler component, inasmuch as the composition of the liquid material can change and, in the case of drugs, the dosage of which can deviate from the target value.

It is also considered to be inventive that a flow homogenizer is arranged downstream of the air bypass opening, the flow resistance of which is less than 1 mbar at an air throughput of 250 mL/sec. Both the vapor-air mixture formed and/or condensation aerosol and the bypass air flowing in through the air bypass opening flow through the flow homogenizer and causes these two flow components to be mixed and homogenized. Concentration peaks are reduced and the homogenized mixture emerging from the mouthpiece opening is more pleasant for the user to inhale. The flow homogenizer can, for example, consist of a non-woven or foam-like material; such a material is capable of generating sufficient flow turbulence and turbulence without exceeding the specified flow resistance limit. Only in this way can the configuration of the invention just described be used for a classic inhaler.

In an optional embodiment of the invention, several composites arranged next to one another with different heat capacities are provided. In a further optional embodiment of the invention, several composites arranged next to one another with different heating element properties are provided. In a further optional embodiment of the Invention, several composites arranged next to one another are provided with electrical heating elements that can be controlled in different ways. In a further optional embodiment of the invention, a plurality of composites arranged next to one another are provided, and liquid materials of different composition are assigned to the individual composites for evaporation, in that their wicks are fed from sources with different liquid material. The design options mentioned above, which can also be combined with one another as desired, make it possible to design the evaporation process to be more variable in terms of space and time. This variability allows even the complex conditions in the distillation zone of a cigarette to be approximately reproduced.

In a special embodiment of the invention, several composites arranged next to one another are provided, the heating elements of which consist of electrical heating resistors; according to the invention, the heating resistors are connected in series with one another. This special design proves to be particularly advantageous if the heating resistors are made of a metallic resistance material such as stainless steel or heating conductor alloys, since the series connection and the associated increase in resistance can limit the heating current to a level that can be controlled by the electronic control and the Energy storage is still well manageable. The increase in resistance also allows the power density in the network to be throttled as required, so that stable evaporation can be guaranteed in any case.

Appropriate and advantageous embodiments of the invention are shown in the drawings and are explained in more detail in the following description.

• Fig.1 einen erfindungsgemäßen Inhalator in einer ersten Ausführungsform, ausgebildet als Zug-Inhalator, in verschiedenen Ansichten;
• Fig. 2 einen Inhalator nach Fig. 1 mit einem wiederverwendbaren Inhalatorteil und einer auswechselbaren Inhalatorkomponente im entkoppelten Zustand;
• Fig. 3 das wiederverwendbare Inhalatorteil in verschiedenen Ansichten;
• Fig. 4 und Fig. 5 das wiederverwendbare Inhalatorteil ohne Batteriedeckel und ohne Schaltkreisdeckel in verschiedenen Ansichten;
• Fig. 6 die auswechselbare Inhalatorkomponente in verschiedenen Ansichten;
• Fig. 7 die auswechselbare Inhalatorkomponente mit getrennt dargestelltem Flüssigkeitsbehälter und Mundstück;
• Fig. 8 den Inhalator nach Fig. 1 ohne Schaltkreisdeckel;
• Fig. 9 einen Längsschnitt durch den Inhalator nach Fig. 8 in Höhe des flächigen Verbundes, wobei die Schnittführung abseits des Verbundes zweckmäßig angepaßt wurde;
• Fig. 10 eine Schnittansicht des Inhalators längs der Linie A-A in Fig. 9 mit Schaltkreisdeckel ;
• Fig. 11 einen Querschnitt des Inhalators nach Fig. 1 in Höhe des flächigen Verbundes;
• Fig. 12 das Detail a aus Fig. 10 in einer vergrößerten Darstellung;
• Fig. 12a das Detail b aus Fig. 12 in einer vergrößerten Darstellung;
• Fig. 13a und Fig. 13b alternative Ausführungsvarianten betreffend das Detail a;
• Fig. 14a, Fig. 14b sowie Fig. 15a, Fig. 15b und Fig. 15c Querschnitte flächiger Verbunde in verschiedenen Ausführungsformen in vergrößerter Darstellung;
• Fig. 16 eine Ausgestaltungsvariante betreffend das Detail b aus Fig. 12 mit drei nebeneinander angeordneten linienförmigen Verbunden;
• Fig. 16a einen Querschnitt eines einzelnen linienförmigen Verbundes nach Fig. 16 in einer vergrößerten Darstellung;
• Fig. 17 das Detail c aus Fig. 11 in einer vergrößerten Darstellung;
• Fig. 18 das Detail d aus Fig. 9 in einer vergrößerten Darstellung;
• Fig. 19 eine Schnittansicht des Inhalators längs der Linie B-B in Fig. 9 mit Schaltkreisdeckel ;
• Fig. 20 eine Schnittansicht der auswechselbaren Inhalatorkomponente längs der Linie C-C in Fig. 7 und Fig. 11 mit angedeutetem Flüssigkeitsbehälter;
• Fig. 21 einen erfindungsgemäßen Inhalator in einer zweiten Ausführungsform, ausgebildet als klassischer Inhalator in einer Ansicht analog zu Fig. 9;
• Fig. 22 eine Schnittansicht des Inhalators nach Fig. 21 längs der Linie D-D in Fig. 21 mit Schaltkreisdeckel;
• Fig. 23 die auswechselbare Inhalatorkomponente des Inhalators nach Fig. 21 in zwei Ansichten;
• Fig. 24a und Fig. 24b eine auswechselbare Inhalatorkomponente mit einem alternativen Flüssigkeitsbehälter-System, wobei die Inhalatorkomponente nach Fig. 24b um den Flüssigkeitsbehälter aufgerissen dargestellt ist;
• Fig. 25 eine Schnittansicht des Inhalators längs der Linie E-E in Fig. 24b;
• Fig. 26 eine auswechselbare Inhalatorkomponente mit einem weiteren alternativen Flüssigkeitsspeicher-System;
• Fig. 27 einen Querschnitt der Inhalatorkomponente nach Fig. 26 in Höhe des flächigen Verbundes;
• Fig. 28 einen Schnitt durch den Flüssigkeitsspeicher nach Fig. 26 quer zum flächigen Verbund;
• Fig. 29 eine auswechselbare Inhalatorkomponente mit zwei nebeneinander angeordneten flächigen Verbunden in einer Schnittansicht, wobei der Schnitt in Höhe der flächigen Verbunde verläuft, und in einer Seitenansicht.

Show it:

• Fig.1 an inhaler according to the invention in a first embodiment, designed as a draw-in inhaler, in different views;
• 2 an inhaler 1 with a reusable inhaler part and an exchangeable inhaler component in the decoupled state;
• 3 the reusable inhaler part in different views;
• 4 and figure 5 the reusable inhaler part without a battery cover and without a circuit cover in different views;
• 6 the exchangeable inhaler component in different views;
• 7 the replaceable inhaler component with the liquid container and mouthpiece shown separately;
• 8 the inhaler 1 without circuit cover;
• 9 a longitudinal section through the inhaler 8 at the level of the two-dimensional composite, with the incision being appropriately adapted away from the composite;
• 10 a sectional view of the inhaler along the line AA in 9 with circuit cover ;
• 11 a cross-section of the inhaler 1 at the level of the surface bond;
• 12 the detail a out 10 in an enlarged view;
• 12a the detail b out 12 in an enlarged view;
• Figures 13a and 13b alternative design variants relating to detail a;
• 14a, 14b as well as Figures 15a, 15b and 15c Cross sections of flat composites in various embodiments in an enlarged view;
• 16 an embodiment variant concerning the detail b 12 with three linear composites arranged side by side;
• 16a a cross-section of a single linear composite 16 in an enlarged view;
• 17 the detail c out 11 in an enlarged view;
• 18 the detail d out 9 in an enlarged view;
• 19 a sectional view of the inhaler along the line BB in 9 with circuit cover ;
• 20 a sectional view of the replaceable inhaler component along the line CC in 7 and 11 with indicated liquid container;
• 21 an inhaler according to the invention in a second embodiment, designed as a classic inhaler in a view analogous to 9 ;
• 22 a sectional view of the inhaler 21 along the line DD in 21 with circuit cover;
• 23 the replaceable inhaler component of the inhaler 21 in two views;
• Figures 24a and 24b a replaceable inhaler component with an alternative liquid container system, the inhaler component according to Figure 24b shown broken away around the liquid container;
• 25 a sectional view of the inhaler along the line EE in Figure 24b ;
• 26 a replaceable inhaler component with another alternative liquid storage system;
• 27 a cross-section of the inhaler component 26 at the level of the surface bond;
• 28 a section through the liquid reservoir 26 transverse to the planar bond;
• 29 a replaceable inhaler component with two planar composites arranged next to one another in a sectional view, the section running at the level of the planar composites, and in a side view.

1 shows a first embodiment of an inhaler according to the invention, which inhaler is designed as a draw inhaler in the specific example, and whose shape and size are designed in such a way that the inhaler can be handled easily and conveniently by users. In terms of volume, the inhaler is only about half the size of a packet of cigarettes. The inhaler shown as an example basically consists of two parts, namely an inhaler part 1 and an inhaler component 2. The inhaler component 2 consists of a housing 3 and includes, among other things, a liquid container 4 and a tobacco pipe-like mouthpiece 5. The liquid container 4 contains a liquid material which vaporized in the inhaler component 2 and converted into an inhalable vapor-air mixture and/or condensation aerosol becomes. The vapor/air mixture formed and/or condensation aerosol is presented to the user via the mouthpiece 5 . In principle, all substances and preparations that can be vaporized largely without residue under atmospheric conditions can be considered as liquid material. This condition is also already met if the respective substance or the respective preparation is diluted, for example dissolved in water and/or ethanol, and the solution evaporates largely without leaving any residue. A sufficiently high dilution in a readily volatile solvent such as ethanol and/or water can also make it possible for substances that are otherwise difficult to vaporize to meet the aforementioned condition, and thermal decomposition of the liquid material can be avoided or significantly reduced.

The liquid material preferably contains a drug. The aerosol particles generated by condensation usually have a mass median aerodynamic diameter (MMAD) of less than 2 µm and thus also reach the alveoli. The inhaler according to the invention is particularly suitable for the administration of systemically acting medicaments such as, for example, those medicaments which develop their main effect in the central nervous system. An example is nicotine, which has a boiling point of 246°C. The aerosol particles containing the drug are mainly deposited in the alveoli, where the drug flashes into the bloodstream. Using the example of nicotine, it should be noted that this reaches its target organ - namely the central nervous system - in a bundled concentration about 7-10 seconds after inhalation. Of course, the inhaler in question could also be operated without pharmaceuticals, for example only with aromatic substances - also in the form of non-medical applications.

As will be explained in detail below, the inhaler part 1 contains at least one energy store and an electrical circuit, the energy store being protected by a battery cover 6 and the circuit being protected by a circuit cover 7 .

As the 2 shows, the inhaler part 1 and the inhaler component 2 are designed to be detachable from one another in the specific exemplary embodiment. The detachable coupling consists of a snap connection, formed by two snap hooks 8 and two detents 9 interacting with these. This arrangement makes the inhaler part 1 reusable, which is fundamentally useful if you Considering that firstly the inhaler part 1 does not come into contact with the liquid material, ie is not contaminated with the liquid material, and secondly contains components which are more durable than the components of the inhaler component 2. The inhaler component 2 is after the liquid material is used up in the liquid container 4, properly disposed of as a whole by the user and replaced with a new inhaler component 2. In this respect, the inhaler component 2 represents a replaceable disposable item. Proper disposal is indicated above all if the liquid material contains medicinal products, because inside the housing 3 of the inhaler component 2 during the formation of the vapour-air mixture and/or condensation aerosol always form and deposit condensate residues. Residues of the liquid material always remain in the liquid container 4 as well. In principle, it would of course also be conceivable for the inhaler part 1 and the inhaler component 2 to be designed in one piece, that is to say inseparable from one another. However, this embodiment is likely to be less economical because in this case all parts and components of the inhaler, ie the inhaler as a whole, form a disposable item for single use. Of course, the subject invention also includes this embodiment, in which case the entire inhaler is to be regarded as an inhaler component.

The Figures 3 to 5 show different views of the reusable inhaler part 1 with and without a lid. The reusable inhaler part 1 is composed essentially of the following three housing parts: the battery cover 6, the circuit cover 7 and a carrier housing 10 arranged between them. The three housing parts are preferably made of plastic for reasons of weight. The support housing 10 accommodates the electrical circuit 11 and the energy store 12 and includes a partition wall 13 which separates the circuit 11 and the energy store 12 from one another. In the exemplary embodiment, the electrical circuit 11 is designed as a printed circuit board populated on one side, which is fastened to the partition wall 13, for example, by means of an adhesive bond. The energy store 12 preferably consists of a rechargeable battery, for example a lithium-ion accumulator or a lithium-polymer accumulator, preferably in a flat design. These battery types currently provide the highest energy densities and currents and have been used in a variety of ways for a long time first and foremost is the widespread use in mobile phones. The power is supplied from the battery 12 to the circuit board 11 via two flat contacts 14, which are soldered to the back of the circuit board 11 - see also 10 . The flat contacts 14 protrude through two somewhat larger windows 15 in the partition wall 13 . The battery 12 includes two mating contacts (not shown) which are pressed against the tabs 14, thereby making releasable electrical contact. The compressive force required for this purpose is preferably generated by a leaf spring (not shown) arranged between the battery 12 and the battery cover 6 . The battery cover 6 is detachably connected to the carrier housing 10 - in the exemplary embodiment by means of a screw connection (see 1 ). Of course, the battery cover 6 could alternatively also be designed as a lockable sliding cover. The circuit cover 7 is preferably inseparably connected to the carrier housing 10, for example by means of an adhesive or welded connection. In this way, an unauthorized manipulation of the circuit 11 is to be counteracted. In the normally rare case of a circuit defect, the entire inhaler part 1, with the exception of the battery 12, must be replaced. Other components and properties of the reusable inhaler part 1 will be described in more detail later.

The 6 and 7 show different views of the replaceable inhaler component 2. As already mentioned, the replaceable inhaler component 2 is essentially formed by the housing 3 and includes, among other things, the liquid container 4 and the tobacco pipe-like mouthpiece 5. The liquid container 4 and the mouthpiece 5 are inseparable from the housing 3 connected. In terms of manufacturing technology, it is favorable to manufacture the liquid container 4 and the mouthpiece 5 as separate parts and only to connect them to the housing 3 in a subsequent step, for example by means of an adhesive or welded connection—see FIG 7 . In principle, it is of course also conceivable for the liquid container 4 and/or the mouthpiece 5 to be designed in one piece with the housing 3 . For reasons of weight, the housing 3, the liquid container 4 and the mouthpiece 5 are preferably made of plastic, the properties of the liquid material 16 having to be taken into account when selecting the material for the liquid container 4. Contains the liquid material 16 for example nicotine, plastics can be in accordance with US 5,167,242 (James E Turner et al. ) and US 6,790,496 (Gustaf Levander et al. ) find use.

The liquid container 4 is filled with the liquid material 16 via a filling hole 17, preferably under a protective gas atmosphere such as argon or nitrogen. On one end of the liquid container 4 there is a flap-like, openable closure 18 which is opened by the user before using the inhaler component 2 by pressing it. The openable shutter 18 will be described later in detail. The liquid container 4 is never completely filled with the liquid material 16. Due to the incompressibility of the liquid material 16, complete filling would result in the flap-like, openable closure 18, which always has a certain elasticity, no longer being able to be pressed in and opened. After filling, the filling hole 17 is hermetically sealed with a sealing cap 19 . The closure cover 19 can, for example, be glued or welded on, in which case the effect of heat on the liquid material 16 should be avoided as far as possible. Alternatively, the filling hole 17 can be designed as a capillary bore, and filling with the liquid material 16 can take place via an injection needle. In this case, the closure cap 19 could be omitted and the capillary bore itself melted shut. Other components and properties of the replaceable inhaler component 2 will be described in detail later.

8 shows the inhaler 1 with lifted circuit cover 7. Among other things, the 8 the snap connection, consisting of the two snap hooks 8 and the corresponding locking lugs 9, in the coupled, locked state. The snap hooks 8 are designed as extensions of the housing 3, while the latching lugs 9 are formed by contact elements 20. The contact elements 20 are attached to the carrier housing 10 of the reusable inhaler part 1 by an adhesive connection and fulfill other functions which will be described in detail later.

The Figures 9 to 13 provide more detailed information about the inner workings of the inhaler and its basic functionality. Accordingly, the housing 3 of the replaceable inhaler component 2 forms a chamber 21 on the inside 11 best shows of one according to the invention sheet-like composite 22 bridge-like and thus interspersed without contact. The flat composite 22 has a foil or strip-like planar shape and consists of a heating element and a wick. The capillary structure of the wick is suitable for absorbing liquid material 16 . The heating element and the wick can be designed and connected to one another in a wide variety of ways. Exemplary forms of embodiment will be described later in detail. The two-dimensional composite 22 rests with two end sections on two electrically conductive, plate-shaped contacts 23, on the surface of which it is also electrically contacted at the same time. The contact is preferably made either by a surface adhesive connection using a conductive adhesive - eg adhesives from Epoxy Technology, www.epotek.com - or by a welded connection. In the case of a welded connection, care must be taken to ensure that the wick or its capillary structure is not impaired by the weld if possible. If necessary, the welding should only be carried out selectively. Regarding the choice of material for the plate-shaped contacts 23, references have already been given earlier.

In the exemplary embodiment, the area between the two plate-shaped contacts 23 defines that heated section of the planar composite 22 which is arranged in the chamber 21 without contact. The non-contact arrangement means that the heat conduction losses in the thickness direction of the planar composite 22 are equal to zero. As a result, this section can heat up to such an extent that the liquid material 16 stored in the wick reaches the boiling point and evaporates. According to the invention, the capillary structure of the wick is largely exposed in said section, at least on one side of the planar composite. As will be explained later in the course of the description of exemplary forms of construction of the composite, this side is preferably the side 24 of the flat composite 22 facing away from the plate-shaped contacts 23. The vapor formed during the evaporation of the liquid material can therefore spread over a wide area and without significant hindrance flow out of the exposed capillary structure of the wick. In a second embodiment of the planar composite, which will also be described later using examples, the capillary structure of the wick in said section is also largely exposed on side 25 of the planar composite 22 opposite side 24, so that the evaporation surface and consequently the maximum achievable evaporation capacity is doubled compared to the first case. The maximum achievable evaporation rate is defined by the first occurrence of a boiling crisis in the wick.

The housing 3 also defines an air inlet port 26 for the supply of air from the environment into the chamber 21. The supplied air mixes in the chamber 21 with the vapor emanating from the exposed capillary structure of the wick, in the course of which the vapour-air Mixture and/or condensation aerosol forms. The air inlet opening 26 is designed as a slit-shaped channel. The slit-shaped channel is aligned parallel to the planar composite 22 . In the embodiment after 10 or. 12 the slit-shaped channel is arranged somewhat laterally offset to the planar composite 22, namely on that side of the planar composite on which the capillary structure of the wick is largely exposed. This arrangement ensures that the air flowing through the slit-shaped channel 26 into the chamber 21 flows completely over the exposed capillary structure of the wick, and homogeneous mixing conditions can be established. By varying the slit height of the slit-shaped channel 26, assuming a constant puff profile (puff volume, puff duration), the flow velocity of the inflowing air can be changed, and in this way the dynamics of the aerosol formation and, in connection therewith, the properties of the aerosol generated can be influenced within certain limits become. A reduction in the flow velocity causes the aerosol particles to increase in size on average. The geometric position of the slit-shaped channel 26 in relation to the flat composite 22 also has an influence on aerosol formation.

The Figures 13a and 13b show alternative arrangements of the air inlet opening 26: accordingly, the air inlet opening 26 in the example shown in FIG 13a formed by two slit-shaped channels 26 which are arranged on opposite sides of the planar composite 22 . The air flowing into the chamber 21 flows around the planar composite 22 on both sides. In the example after Figure 13b the slit-shaped channel 26 is arranged centrally to the planar composite; In this case, the planar composite 22 lies in the plane of the slot-shaped channel and the inflowing air flows directly against it, with the air flow being split into two parts by the planar composite, and the composite consequently flowing around on both sides as in the previous example becomes. The orders after Figures 13a and 13b are particularly suitable for the embodiment variant of the planar composite 22 in which the capillary structure of the wick is exposed on both sides, since in this case steam flows off from both sides 24 and 25 of the planar composite 22 . However, they are also suitable for the variant of the planar composite 22 with a capillary structure that is only exposed on one side, insofar as the second air flow component, which flows around the composite in a quasi-passive manner, weakens the first air flow component that causes the aerosol formation, which in turn influences the properties of the aerosol formed can be.

The air inlet opening 26 designed as a slit-shaped duct draws the air from a plenum chamber 27, which serves to distribute the air evenly over the slit-shaped duct 26, so that essentially the same flow conditions prevail in the slit-shaped duct on all sides. Upstream of the plenum chamber 27 is a flow restrictor 28. The purpose of the flow restrictor 28 is to create a flow resistance similar to that of a cigarette so that the user experiences a similar drag during a puff as when puffing on a cigarette. Specifically, the flow resistance should be in the range of 12-16 mbar at a flow rate of 1.05 L/min and have a characteristic that is as linear as possible. The flow restrictor 28 can be formed, for example, from an open-pored sintered body made of metal or plastic, through the pores of which the air flows. For example, porous plastic moldings from Porex, www.porex.com, have proven successful in prototypes. In the exemplary embodiment, the plenum chamber 27 is part of the replaceable inhaler component 2 and the flow restrictor 28 is part of the reusable inhaler part 1. In principle, it would also be possible to arrange the plenum chamber 27 and the flow restrictor 28 in the replaceable inhaler component 2, or alternatively to arrange both in the reusable inhaler part 1.

The 10 shows the further course of the air flow upstream of the flow throttle 28. The flow is indicated by arrows. Accordingly, the flow restrictor 28 draws the air from a transverse channel 29 which in turn opens into the space between the circuit board 11 and the circuit cover 7 . The actual supply of air from the environment takes place via a feed opening 30 formed by the circuit cover 7. The feed opening 30 is on the the mouthpiece 5 opposite end face of the inhaler. This position provides the best protection against the ingress of rainwater.

The 14a, 14b and 15a, 15b, 15c show exemplary configurations of the planar composite 22 based on cross-sectional representations, with "cross-section" being understood to mean a section normal to the longitudinal direction of the composite (cf. 9 ). Specifically, they show Figures 14a and 14b Embodiments with capillary structure exposed only on one side, while the Figures 15a to 15c Show embodiments in which the capillary structure of the wick is exposed on both sides of the planar composite. According to the embodiment according to 14a the flat composite 22 consists of four layers: namely a metal foil 31 and three metal wire meshes 32 sintered onto it. The metal consists of stainless steel (e.g. AISI 304 or AISI 316) or of a heating conductor alloy - in particular from the group of NiCr alloys or CrFeAl -Alloys ("Kanthal"). When using stainless steel, preference is given to low-carbon charges (eg AISI 304L or AISI 316L) because they are less susceptible to intergranular corrosion. The metal foil 31 can be obtained in a stainless steel design, for example from Record Metall-Folien GmbH, www.recordmetall.de. The wire mesh can be obtained, for example, from the companies Haver & Boecker, www.haverboecker.com or Spörl KG, www.spoerl.de. The four layers are connected to each other by sintering. The sintering is preferably carried out in a vacuum or under a protective hydrogen gas. Such sintering is part of the prior art and is routinely carried out, for example, by GKN Sinter Metals Filters GmbH, www.gkn-filters.com, and by Spörl KG, www.spoerl.de. The sintering is advantageously carried out in the form of a multiple panel; This means that not individual flat composites are sintered, but larger flat panels, for example in the 200x200mm format. After sintering, the individual composites are obtained from the multiple panel by laser cutting or punching and then optionally etched in a pickling bath.

Table 1 shows an example of the specifications of flat composites 22 used in prototypes. <u>Table1</u>: Metal foil thickness: 10µm Metal Foil Material: AISI 304 1. wire mesh layer: 36×90µm Wire diameter × mesh size 2. wire mesh layer: 30×71µm Wire diameter × mesh size 3. wire mesh layer: 20×53µm Wire diameter × mesh size Wire Cloth Material: AISI 316L Composite span: 14mm Compound width: 2-5mm Composite Thickness: 140-160µm Etch Rate : until 50% with bath stain Avesta 302 ^∗ ) Porosity: 65-80% depending on the etch rate ^∗ ) Manufacturer: Avesta Finishing Chemicals, www.avestafinishing.com

The composite span corresponds to that distance in the chamber 21 which the composite 22 bridges without contact; In the specific embodiment, this distance corresponds to the distance between the two plate-shaped contacts 23. The bond span and the bond width have an opposite influence on the resulting heating element resistance. The etch rate defines the total mass loss achieved by the etch. The first layer of wire mesh rests directly on the metal foil 31 . The third wire mesh layer forms the top layer and at the same time the exposed capillary structure of the flat composite 22. The flat composite 22 is preferably positioned with the metal foil 31 on the plate-shaped contacts 23. The electrical contacting of the metal foil 31 is preferably carried out via a flat adhesive connection between the metal foil 31 and the electrically conductive, plate-shaped contacts 23. In principle, the contact could also be made by a welded connection. A flat composite 22 contacted in this way with the specifications according to Table 1, with a composite width of 2 mm and an etching rate of 35% has a heating element resistance of about 310 mOhm. When using heating conductor alloys instead of stainless steel, the heating element resistance can be significantly increased, specifically when using DIN material number 2.4872 (NiCr20AISi) compared to AISI 304/AISI 316 by a factor of 1.8 and when using DIN material number 1.4765 (CrAl255) by a factor of 2.0. As a result, a flat bond with a bond width of 5 mm in the form of DIN material number 2.4872 but otherwise the same specifications as mentioned above would have a heating element resistance of around 225 mOhm. If the energy supply is based on a lithium-polymer cell with a nominal or no-load voltage of 3.7V and a useful voltage under load of approx. 3.1V, the current flowing through the flat compound is calculated on the basis of Ohm's law, to 10A (for 310mOhm) or 13.8A (for 225mOhm). These amperages can easily be obtained from today's lithium polymer cells. In a further step, the rated electrical power is calculated, which is also the maximum heat output that can be achieved at 31W (for 310mOhm) or 42.7W (for 225mOhm). As will be described later, these powers can be arbitrarily reduced by the electrical circuit 11.

Based on the previously mentioned specifications of an exemplary planar composite with a composite width of 5 mm and an etching rate of 35%, the pore volume of the planar composite 22 in the section of the composite span (evaporation section) is calculated to be approximately 7.5 μL. This volume is filled by the liquid material 16 to be vaporized and corresponds to the maximum amount of liquid material that can be vaporized per puff or inhalation (intermittent inhaler operation). For example, if the liquid material contains nicotine as a medicinal product in a concentration of typically 1.5% by volume, this theoretically results in a maximum released nicotine dose of 110µg per vaporization or puff or, calculated over 10 inhalations, a total dose of 1.1mg. In reality, the maximum achievable dose will be slightly below the calculated values for various reasons. What is important, however, is the fact that the nicotine doses of today's cigarettes (0.1-1.0 mg) can be administered without any problems using the inhaler according to the invention. It is also essential that the dose of active ingredient can be reduced as desired, either by reducing the concentration of active ingredient in the liquid material, by choosing a smaller composite width, or by throttling the heating power supplied by means of the electrical circuit 11 The latter measure also has a thermal effect Against decomposition of the liquid material 16, since the composite 22 is not heated as high.

It should be noted that both the metal foil 31 and the metal wire mesh 32 sintered onto the foil contribute to the electrical heating resistance. In this respect, the electrical heating resistance can be interpreted as a parallel connection of these individual resistances. The capillary effect of the wick is also based on the interaction of the wire mesh 32 with the metal foil 31, with even a single wire mesh layer in combination with the metal foil 31 being able to produce a capillary effect. Of course, the invention is not limited to the specifications mentioned above. It would also be possible to arrange other open-pored metal structures on the metal foil 31 instead of the metal wire mesh 32; furthermore, a fabric or other open-pored structures made of an electrically non-conductive material, such as quartz glass, for example, could also be arranged on the metal foil 31 or fried onto it.

Figure 14b shows a second exemplary embodiment of a planar composite 22 with a capillary structure that is only exposed on one side. This embodiment differs from that shown in FIG 14a only in that instead of the two outer wire mesh layers, a fiber composite in the form of a fleece 33 is provided, which is sintered onto the first wire mesh layer 32. Such fleeces 33 can be made in stainless steel, for example, by the company GKN Sinter Metals Filters GmbH, www.gkn-filters.com according to customer specifications. The fleece 33 preferably has a thickness of 100-300 μm and a porosity >70%. The fleece 33 forming the exposed capillary structure of the wick has a significantly larger surface area in comparison to the wire mesh 32; the larger surface has a favorable effect on the evaporation process. The fleece 33 can, of course, also be made from a heat conductor alloy--in particular from the group of NiCr alloys or CrFeAl alloys ("Kanthal"); for this purpose, only the raw fibers forming the fleece 33 are to be produced in these material specifications. The flat composite 22 can optionally be etched again after sintering.

Figure 15a shows an embodiment of a planar composite 22 with a capillary structure exposed on both sides. The planar composite consists accordingly of a open-pored sintered structure formed from a homogeneous granular, fibrous or flaky sintered composite 34. The production of thin porous sintered composites has been known for a long time. US 3,433,632 (Raymond J. Elbert ) describes, for example, a process for the production of thin porous metal plates with a thickness from 75 µm and a pore diameter between 1-50 µm. Among other things, powders made of nickel and stainless steel (AISI 304) were processed. Porosities of up to 60% are achieved, and in a variant with a multi-layer structure even porosities of up to 90% (but only in the top layers). US 6,652,804 (Peter Neumann et al. ) describes a similar procedure. JP 2004/332069 (Tsujimoto Tetsushi et al., Mitsubishi Materials Corporation ) describes a further developed process for the production of thin, porous sintered metal composites in the preferred thickness range of 50-300 µm, which is characterized by the fact that removable fillers, in this specific case acrylic resin beads, are added to the metal powder to be processed. The acrylic resin beads are placeholders, which sublime in a vacuum at around 500°C in the course of a heat treatment before the actual sintering, leaving cavities which remain during and after the sintering. In this way, flat composites consisting of stainless steel of specification AISI 316L with porosities of typically 70-90% were produced. The Institute for Energy Research (IEF) of the Research Center Jülich, www.fz-juelich.de/ief/ief-1 is also able to produce thin, porous metal foils up to a thickness of 500 µm. Like the aforementioned process, the production method is based on what is known as the doctor blade film casting process.

In principle, all the methods mentioned can be used for the production of a flat sintered composite 22, 34 according to the invention, with the method according to JP 2004/332069 is given preference because of the high porosity achieved. It should only be noted that the average pore diameter in the homogeneous sintered composite is >10 μm if possible, in order to ensure sufficiently rapid infiltration of the wick with the liquid material 16 . The grain size of the metal powder to be processed and the acrylic resin beads must be matched to this condition. The one in the process JP 2004/332069 The preferred thickness range of 50-300 μm mentioned coincides with the thickness range particularly preferred for the planar composite 22 .

In addition to processing stainless steel, the methods mentioned are also suitable for processing powdered heat conductor alloys and powdered ceramic resistance materials.

Figure 15b shows a further development or modification of a planar composite according to the embodiment Figure 15a , in that channels or arteries 35 are arranged in the planar composite 22 in the longitudinal direction of the composite, the advantageous effects of which have already been described earlier. The production of these channels 35 requires an adaptation of the aforementioned production methods, in that threads that can be removed by oxidation, sublimation or chemical decomposition, for example sublimable acrylic resin threads, are introduced into the film casting slip. The threads are placeholders which, in the course of their removal, leave cavities forming channels 35 behind. This is best done in three process steps: first, a first film layer is cast. A layer of threads aligned parallel to one another, which later form the arteries 35, is placed on this. Finally, a second film layer is cast, which at the same time forms the top layer. For better handling, the threads are stretched in an auxiliary frame before they are applied. In this modified embodiment, the grain size of the metal powder to be processed and, if necessary, the acrylic resin beads is preferably in the range of 1-10 μm, while the preferred diameter range of the threads is 20-150 μm. In an optional method step following the film casting and sintering, the flat sintered composite 22, 34 is perforated in the thickness direction, as a result of which holes 36 are formed. The perforation can be done, for example, by means of a laser. The hole pattern should be chosen as non-uniform as possible; With a uniform grid, the unfavorable case could occur that all the holes 36 come to lie between the arteries 35 and the arteries are not cut. In this case, the advantageous effects of the perforation already described earlier would only partially appear.

To further increase the porosity and the electrical resistance, the composites according to the statements Figures 15a and 15b optionally etched again after sintering. The attachment and contacting of the flat sintered composite 22, 34 on the plate-shaped contacts 23 is preferably carried out by a welded connection. An adhesive connection is only possible if the adhesive used is sufficiently pasty or viscous has consistency. Otherwise there would be a risk of the adhesive entering the pore structure of the composite and impairing the capillary action of the wick. If necessary, it can be advantageous to suspend the perforation of the composite in the area of the adhesive bond.

Figure 15c finally shows a further embodiment of a flat composite 22 with a capillary structure exposed on both sides. Accordingly, the planar composite 22 consists of an open-pored foam 37 formed from an electrical resistance material. The production of foam-like composites has been known for a long time. So describes US 3,111,396 (Burton B. Ball ) already has a process for the production of metal foams, ceramic foams and graphite foams. The method is based on an organic porous structure being impregnated with a slip containing the foam-forming material, and the organic structure decomposing in the course of a subsequent heat treatment. In this way, among other things, foams made of nickel and nickel-based alloys were produced. Thin, film-like foams with a thickness in the range of 100-500 μm, a preferred pore diameter in the range of 20-150 μm and a porosity of >70% are required for a planar composite 22 according to the invention. Such a foam material can be obtained in a stainless steel version (eg AISI 316L) from Mitsubishi Materials Corporation, www.mmc.co.jp. This is based on a standard foam material with a thickness of 0.5 mm, a pore diameter in the range of 50-150 µm and a porosity of around 90%, which material can be compacted in any thickness by rolling down to around 100 µm. The compacted material can then optionally be sintered. Of course, the compaction also reduces the porosity, which can be increased again if necessary in the course of a final etching treatment. The method of making the standard foam material is also based on the processing of a slip, but differs from the method described above U.S. 3,111,396 in that the actual foam formation takes place through a foaming or blowing agent which is added to the slip. Heating conductor alloys - in particular from the group of NiCr alloys and CrFeAl alloys ("Kanthal") can of course also be processed. The planar composite 22 can consist of a single foam layer or of several layers together sintered foam layers. To increase the stability and strength of the planar composite 22, the foam 37 can optionally be sintered onto a thin carrier layer 38, for example onto a wire mesh made of stainless steel or a heat conductor alloy. With regard to the fastening and contacting of the foam 37 on the plate-shaped contacts 23, the same applies as in connection with the embodiments according to FIG Figures 15a and 15b was executed.

It should be noted that all the previously described forms of construction of the planar composite 22 only represent exemplary embodiments. The invention is in no way limited to these exemplary embodiments. For example, a flat foam material could be sintered onto a metal foil. Furthermore, an open-pored, porous deposition layer could be applied to a metal foil—for example, based on the method shown in FIG DE 1,950,439 (Peter Batzies et al .). Finally, the planar composite could of course also be formed from non-metallic materials such as carbon fibers or graphite fibers, e.g. in the form of fabrics and fleeces, or from quartz glass, e.g. in the form of a granular or fibrous sintered composite, in which case a conductive thin layer applied to the glass surface is the could cause electrical resistance heating. Quartz glass is characterized by high chemical resistance and thermal shock resistance.

Figures 16 and 16a show an exemplary embodiment of a linear composite 39, wherein in the present exemplary embodiment three parallel linear composites 39a, 39b, 39c (39c is not shown) are provided. By providing a plurality of linear composites, the evaporation area can be significantly increased in comparison to a single linear composite, assuming the same total cross sections. The individual composites do not necessarily have to have identical properties. For example, it is possible to assign different heat capacities and/or different heating element properties to the individual composites 39a, 39b, 39c. The resulting effects have already been presented earlier.

In the specific example, the linear composites are designed as wire-shaped sintered composites with an open-pored sintered structure 34 . The wire-shaped sintered composites 39a, 39b, 39c rest on the plate-shaped ones Contacts 23 in recesses 108, whereby the wire-like sintered composites are positioned. In the specific exemplary embodiment, the electrical contact is made by clamping, in that the wire-shaped sintered composites 39a, 39b, 39c are pressed against the plate-shaped contacts 23 by a scaffold-like pressing die 40 (see arrow in 16a ). The wire-shaped sintered composites 39a, 39b, 39c are preferably produced by means of an extrusion process, for example according to FIG AU 6,393,173 (Ralph E. Shackleford et al. ). AU 6,393,173 describes the production of stainless steel wires with a wire diameter of 0.3-2.0 mm. In any case, this diameter range also covers the preferred diameter range for the linear composite according to the invention. Specifically, the manufacturing process is based on the extrusion of a mixture consisting of a metal powder, a binder and a plasticizer, and the sintering of the extrudate. The metal powder can be in a granular, fibrous, or flaky form. In order to obtain an open-pored, porous sintered body, the process must be adapted. The adaptation consists in adding a removable filler, for example sublimable acrylic resin beads, to said mixture. The acrylic resin beads are placeholders, which sublimate practically without residue during a heat treatment before the actual sintering at about 500°C and leave cavities. If necessary, the type and amount of the binder and plasticizer must be adjusted to the addition of filler. The particle size of the metal powder to be processed and the acrylic resin beads should be adjusted in such a way that the average pore diameter of the resulting homogeneous sintered composite is >10 µm if possible; this ensures sufficiently rapid infiltration of the wick with the liquid material 16 . Instead of high-grade steel powder, it is of course also possible to use powders made from heat conductor alloys, in particular from the group of NiCr alloys and CrFeAl alloys ("Kanthal"), to be extruded and sintered according to the method.

In general, the assemblies 22 and 39 should be cleaned prior to assembly and the surface of the capillary structure should be activated. This measure brings about improved wetting of the composite material by the liquid material 16 and, associated with this, faster infiltration of the wick. In the case of stainless steel, for example, a treatment with 20% phosphoric acid is sufficient to achieve the aforementioned effects.

The supply of the assembly 22, 39 with the liquid material 16 is to be described in more detail below. The following statements apply equally to planar and linear composites 22, 39, even if the figures are limited to showing only one embodiment of the composite. How 12a and 17 as well as Figures 16 and 16a show, one end of the composite 22, 39 protrudes into a capillary gap 41. The capillary gap 41 feeds the wick of the composite with the liquid material 16; As can be seen from the figures, the cross section of the capillary gap 41 is larger than the cross section of the composite 22, 39. This has the effect that the liquid material 16 flows mainly through the clear cross section of the capillary gap 41 to the evaporation zone, whereby the wick infiltrates more quickly can be, and the waiting time between two trains or inhalations can be shortened. The effect works at least up to the opening of the capillary gap 41 into the chamber 21. From this point the wick of the assembly 22, 39 alone is responsible for the liquid transport. The capillary gap 41 is basically formed by one of the two plate-shaped contacts 23 and an upper part 42 placed flat on this, in that corresponding recesses forming the capillary gap 41 are incorporated into the upper part 42 and into the plate-shaped contact 23 - see 12a and 17 . It should be noted that even a single recess, whether it is arranged in the upper part 42 or in the plate-shaped contact 23, would be sufficient to form a capillary gap 41. When using a flat composite 22, it is in any case advantageous to arrange the recess in the plate-shaped contact 23, since in this case the recess can be used at the same time as a positioning aid for the composite 22. The upper part 42 is preferably joined to the plate-shaped contact 23 by an adhesive connection and consists of a material that can be easily wetted with the liquid material 16, preferably a light metal or a wettable plastic; the wettability and also the bondability of plastics can be significantly improved by surface activation, for example by plasma treatment with oxygen as the process gas.

Further upstream, the capillary gap 41 is formed by two thin plates 43 arranged parallel and spaced apart (see FIG 17 ), One plate being connected to the upper part 42 and the other plate to the plate-shaped contact 23, preferably by an adhesive connection. The plates 43 can be punched out of a stainless steel strip, for example. How 18-20 best show, the plates 43 forming the capillary gap 41 project into a reservoir 45 via an extension 44 . The reservoir 45 connects directly to the liquid container 4 and is separated from it only by the flap-like closure 18 that can be opened. The openable closure 18 is opened with the aid of a pin 46 . The pin 46 is mounted in the housing 3 in an axially displaceable manner and is preferably made of stainless steel. A first end 47 of pin 46 is directed toward openable closure 18 . A second end 48 protrudes from the outer surface of the housing 3 in the manner of an extension when the closure 18 is still closed. The second end 48 of the pin 46 is in a plunger-like operative connection with one of the two contact elements 20 of the inhaler part 1, in that the contact element 20 presses against the second end 48 of the pin 46 in the course of coupling the inhaler component 2 to the inhaler part 1, and the pin 46 is thereby displaced into the housing 3. The compressive force exerted by the contact element 20 is transmitted from the pin 46 to the openable closure 18. The openable closure 18 has a material weakening 49 on its circumference, which is dimensioned such that it tears open like a predetermined breaking point over a wide circumferential area when pressure is applied by the pin 46, but forms a hinge 50 on one side. In this way, the openable shutter 18 is caused to open like a flap. The pin 46 has near the first end 47 a cross-sectional widening 51 which, like a stop, prevents the pin from sliding out of the housing 3 or being able to be removed.

The supply of the composite 22, 39 with the liquid material 16 will be explained in summary below, the 18 and 20 the flow conditions are illustrated by arrows: in the course of coupling the inhaler component 2 to the reusable inhaler part 1, the flap-like closure 18 is opened via the pin 46 and the reservoir 45 is then flooded with the liquid material 16 under the influence of gravity. In 19 the liquid levels before and after flooding are shown. The capillary gap 41 sucks in the liquid material 16 via the extension 44 and feeds it to the composite 22, 39, as a result of which the wick is finally completely infiltrated with the liquid material 16. The extension 44 formed by the plates 43 is intended to prevent gas bubbles from forming in the mouth area of the capillary gap 41 settle, which could impede the capillary coupling. Furthermore, a ventilation channel 52 is worked into the plate-shaped contact 23, which connects the reservoir 45 to the chamber 21. The function of the ventilation channel 52 has already been explained earlier. The ventilation channel 52 opens into the chamber 21 preferably at a point upstream of the assembly 22, 39, since in this area of the chamber 21 hardly any condensate deposits are to be expected; Such condensate deposits could namely block the ventilation duct 52 or reach the reservoir 45 via the ventilation duct 52 and contaminate the liquid material 16 stored there. Finally, a buffer memory 53 is integrated into the upper part 42 - see also 11 and 17 , the effect of which was also explained earlier. In the present exemplary embodiment, the buffer store 53 consists of slots 54 which are arranged parallel to one another and which are incorporated into the upper part 42 . The slits 54 communicate on the one hand via openings 55 with the capillary gap 41 and on the other hand via an aeration gap 56 with the chamber 21. The capillarity of the slits 54 causes the liquid material 16 to flow out of the reservoir 45 via the capillary gap 41 and via the openings 55 into the Slots 54 where it is temporarily stored and can be withdrawn from the wick as needed.

Figures 9-12 also show a condensate binding device arranged in the chamber 21 consisting of two open-pored, absorbent bodies or sponges 57. The effects of the condensate binding device and its necessity for the inhaler component according to the invention have already been explained in detail earlier. The two sponges 57 are plate-shaped and spaced apart and arranged parallel to one another, the composite 22 being covered by the two sponges 57 on both sides. A flow channel 58 is formed between the two sponges 57, in which the formation of the vapour-air mixture and/or condensation aerosol takes place. The main part of the condensate residues is deposited on the wall sections 59 of the sponges 57 forming the flow channel 58 and immediately sucked up by the open pore structure of the sponges. The sponges 57 are attached to two opposite walls of the chamber 21, for example by means of an adhesive bond, fill the majority of the chamber 21 and are preferably made of a highly porous, dimensionally stable and possibly fine-pored material. If coarse-pored material is used, there is a risk that in the event of abrupt movements or accelerations of the inhaler component 2 the capillary forces of the sponge material will no longer be sufficient to hold back the liquid condensate and parts of the condensate will be thrown out of the sponges 57 . Fiber composites, formed from natural or man-made fibers that are thermally bonded to one another or with the aid of a binder, have proven to be particularly suitable as sponge material. Filtrona Richmond Inc., www.filtronaporoustechnologies.com, specializes in the production of such fiber composites, using triacetin-bonded cellulose acetate fibers as well as thermally bonded polyolefin and polyester fibers.

The sponges 57 are arranged somewhat spaced apart from the upper part 42 and from the plate-shaped contact 23 connected to the upper part 42, so that a gap 60 is formed. The gap 60 ensures that the ventilation channel 52 and the ventilation gap 56 can communicate with the chamber 21 unhindered. The sponges 57 are to be dimensioned in such a way that their pore volume is able to absorb the expected amount of condensate residues formed. The amount of condensate depends primarily on the proportion of the liquid material 16 in low-boiling fractions with high vapor pressure and the air flow rate through the air inlet opening 26 and through the flow channel 58 from. The less air that is pushed through, the less vapor the air can absorb up to saturation.

How Figures 9-10 and 12 show, the sponges 57 are downstream of the composite 22, a cooler 61, which consists of a porous filling material 61 in the specific embodiment, the pores of which flows through the formed vapor-air mixture and / or condensation aerosol. The essential effects of the cooler or filling material 61 have already been explained in detail earlier. The filling material 61 is located in a filling space 62 which is delimited by a perforated wall 63 on the flow inlet side, by the mouthpiece 5 on the flow outlet side, and by the housing 3 and a wall of the liquid container 4 on the casing side. The perforated wall 63 supports the filling material 61 and at the same time stiffens the housing 3 . The hole wall 63 is arranged somewhat spaced from the sponges 57 - see 12 . This ensures that the flow channel 58 escaping vapor-air mixture and/or condensation aerosol can be distributed evenly over the entire cross-section of the filling material 61 before the perforated wall 63, and the filling material 61 flows evenly through it. A first wire mesh 64 is arranged between the filling material 61 and the perforated wall 63 so that the filling material 61 cannot escape from the holes in the perforated wall 63 . On the mouthpiece side, the filling material 61 is delimited by a second wire mesh 65, which prevents the filling material from getting into the mouthpiece channel 66 or even into the user's oral cavity. The mouthpiece forms a collection chamber 67 between the second wire mesh 65 and the mouthpiece channel 66, which causes the filling material 61 to flow through evenly even in the end section. The second wire mesh 65 is advantageously attached directly to the mouthpiece 5, eg melted onto it. In the course of assembly, the first wire mesh 64 is placed on the perforated wall 63 first. Thereafter, a predefined amount of filling material 61 is introduced into the filling space 62, with the filling also being able to take place in several stages, and the filling material 61 being intermediately compressed after each partial filling. In this way, a homogeneous filling density can be achieved. Alternatively, the filling material 61 could already be prepacked outside of the inhaler component 2, for example in paper cylinders with a cross section adapted to the filling space 62, and the pack inserted into the filling space 62. Such packages can be obtained economically from a continuous strand. Finally, the mouthpiece 5 is mounted and the filling space 62 is closed.

The filling material can consist of a regenerator material, for example. Especially when the liquid material 16 contains nicotine, it proves to be particularly advantageous to use tobacco as the filling material 61 . Excellent results were achieved in prototypes based on fine-cut tobacco and a filling volume of around 7 cm3 with regard to the organoleptic effects of the administered vapour-air mixture or condensation aerosol. The tobacco can be additionally flavored by adding aromatic additives and essential oils such as tobacco extract, tobacco aroma oils, menthol, coffee extract, tobacco smoke condensate or a volatile aromatic fraction of a tobacco smoke condensate. Of course, the invention is not limited to this selection.

The filling density of the filling material 61 determines the flow resistance which the filling material 61 opposes to the vapor/air mixture or condensation aerosol; the filling density is to be matched to the flow resistance of the flow restrictor 28 in such a way that the resulting flow resistance is within the already mentioned range of 12-16 mbar at an air throughput of 1.05 l/min. In principle, it is also possible to do without the flow restrictor 28 entirely and to generate the desired flow resistance solely through the filling material 61 by increasing its filling density accordingly. In general, however, it should be noted that a filter effect is undesirable; the aerosol particles generated in the chamber 21 should be able to penetrate the filling material 61 with as few losses as possible. The alternative embodiment variant without a flow throttle 28 also has an effect on the sensor-based detection of the start of the train, which effects will be explained in more detail later. If the filling material 61 contains tobacco and/or flavorings, the inhaler component 2 should be kept in an airtight package until it is used in order to prevent flavorings from escaping. Even after the inhaler component 2 has been coupled to the inhaler part 1, it is possible, by closing the mouthpiece channel 66, for example by means of a cap or a plug (not shown), for flavoring substances to escape and for evaporation and fractions of the liquid material stored in the wick to escape 16 largely ruled out.

21-22 show a second embodiment of an inhaler according to the invention, and 23 shows a replaceable inhaler component for this inhaler. In the specific example, the inhaler is designed as a classic inhaler and is largely based on the arrangement shown in FIG Figures 9-10 , but differs from this in that a significantly larger volume of air can be passed through, thereby enabling direct lung inhalation in a single step. Concretely, the inhaler differs from the arrangement according to FIG Figures 9-10 in that both the flow restrictor 28 and the second open-pored body 61 are omitted, and the mouthpiece channel 66 has a significantly larger cross section. In this way, the flow resistance is significantly reduced. Another essential difference is that the main part of the air that passes through the compound 22, 39 does not happen at all, but flows into the inhaler only downstream of it. For this purpose, two bypass openings 68 are arranged downstream of the assembly 22, 39 on opposite sides of the housing 3, the combined cross section of which is significantly larger than the cross section of the air inlet opening 26. Two guide vanes 69 formed by the housing 3 connect to the two bypass openings 68, which in the direction of the mouthpiece channel 66 and tend towards one another, and whose free ends or tips 70 form a nozzle-shaped orifice opening 71 through which the vapor-air mixture formed and/or condensation aerosol flows out of the chamber 21 and then together with the out of the bypass openings 68 incoming air mixes. The effects of the guide vanes 69 have already been explained earlier. For better mixing of the vapor-air mixture and/or condensation aerosol with the bypass air flowing in through the bypass openings 68, a flow homogenizer 72 can optionally be arranged in the mouthpiece channel 66—see FIG 22 . The flow homogenizer 72 can be made of a fleece-like synthetic fiber material, for example. The company Freudenberg Vliesstoffe KG, www.freudenberg-filter.com, offers such a material in the form of mats/plates under the name Viledon ^® filter mats. The material can be made to customer specifications. In particular, the material properties can be adjusted in such a way that the end product is largely permeable to the fine particles of the condensation aerosol produced and the flow resistance is within the previously specified target range. The mats/plates are made of polyolefin fibers (PE, PP) or polyester fibers and can be further processed by punching.

24-25 show an exchangeable inhaler component 2 of an inhaler according to the invention with an alternative liquid container system. Although the replaceable inhaler component 2 in the specific example represents an inhaler component for use in a classic inhaler, the alternative liquid container system shown can also be used in an inhaler component of a draw-in inhaler, as described above. As the figures show, the liquid container 4 is arranged in the housing 3 so that it can be manually displaced along a displacement axis Y between two stop positions. The Figure 24b shows the liquid container 4 in the first stop position, which at the same time defines its starting position. The first stop position is defined by a projection 73 formed by the mouthpiece 5 in cooperation with a pin 74 formed by the liquid container 4 . The projection 73 makes it impossible to remove the liquid container 4, which may contain medicines and/or poisons, from the inhaler component 2. At the same time, the pin 74 prevents the liquid container 4 from rotating, in that the pin 74 engages in a corresponding groove 75 in the housing 3 . In the starting position, the liquid container 4 protrudes with an end section laterally next to the mouthpiece 5 out of the housing 3 . The displaceable liquid container 4 can be easily slid into its second stop position by the user pressing on the protruding end of the liquid container 4 . The liquid container 4 is thereby shifted by the distance s. The second stop is formed by the upper part 42 and the plate-shaped contact 23 connected to it. The ventilation opening 76 and the ventilation channel 77 prevent the formation of disruptive air cushions during the displacement process. The liquid container 4 has two openings 78, 79 on the end face facing the second stop, which are closed by means of a film seal 80 on the inside of the container. The capillary gap 41 is essentially identical to the arrangement previously described. The plates 43 again form an extension in the form of a first mandrel 81. The first mandrel 81 is positioned to align with the first aperture 78 and the latter in the second Stop position penetrates. The obliquely pointed end of the first mandrel 81 simultaneously cuts through the foil seal 80 and comes into contact with the liquid material 16, as a result of which the capillary coupling with the capillary gap 41 is finally established. The situation is analogous with the ventilation channel 52: in contrast to the arrangement described earlier, in the specific exemplary embodiment this is integrated into the upper part 42 and, like the capillary gap 41, forms an extension or second mandrel 82 at the end facing the liquid container 4, which is positioned so that it is aligned with the second opening 79 in the liquid container 4 and passes through it in the second stop position. The second end of the ventilation channel in turn communicates with the chamber 21 (not shown). The supply of the network 22, 39 with the liquid material 16 functions in the same way as previously described. When the inhaler component 2 is delivered, the liquid container 4 is in its initial position, ie in the first stop position. The liquid container 4 is preferably pushed into the second stop position and coupled to the capillary gap 41 just before the use of the inhaler component 2 . In order to rule out premature, unintentional coupling, the liquid container 4 is fixed in its initial position. The fixation can, like Figure 24b shows, for example by means of a semi-circular locking plate 109, which is connected via micro-bridges 83 on the one hand to the liquid container 4 and on the other hand to the housing 3. In this way, the small locking plate 109 creates a rigid connection between the liquid container 4 and the housing 3 . The micro-webs 83 can be broken and the fixation of the liquid container 4 can be canceled by manual force being applied to the small locking plate 109--for example by bending the same several times. Alternatively, the liquid container 4 can be fixed in a simple manner by means of an adhesive tape (not shown). With regard to the choice of material for the liquid container 4, references have already been made which apply equally to the specific exemplary embodiment.

26-27 show an exchangeable inhaler component 2 of an inhaler according to the invention with a further alternative liquid storage system. Although the replaceable inhaler component 2 in the specific example represents an inhaler component for use in a classic inhaler, the alternative liquid storage system shown can also be used in an inhaler component of a draw-in inhaler, as described earlier. In the specific exemplary embodiment, the liquid reservoir contains an open-pore foam 84 soaked with the liquid material 16. The composite 22, 39 is sandwiched between the foam 84 and one of the two plate-shaped contacts 23, whereby the wick is capillary coupled to the liquid material 16. The foam 84 is held by a cartridge housing 85, with which it forms an exchangeable cartridge 86 together. The cartridge 86 is inserted into a corresponding recess 87 in the housing 3 . The recess 87 is closed airtight by a cover 88 to the outside.

The cover 88 is fixed to the housing 3 by means of a snap connection 89 . This fixation also causes the cover 88 to exert a compressive force on the cartridge 86 in the direction of the composite 22, 39. How 28 shows in more detail, the composite 22, 39 rests on an elevation 90 of the plate-shaped contact 23. The elevation 90, together with the compressive force acting on the cartridge, causes a compression of the foam 84—see compression stroke h. The compression has the effect of forcing a small amount of the liquid material 16 out of the foam 84 in the area of contact with the composite, an amount sufficient to ensure capillary coupling between a newly inserted cartridge 86 and the wick. The cartridge housing 85 is perforated on the side facing the cover 88 . The ventilation holes 91 communicate with the chamber 21 via a recess 92 in the cover 88 and in this way bring about a pressure equalization between the liquid material 16 bound in the pores of the foam 84 and the chamber 21. The foam 84 preferably consists of a fine-pored polyether PUR -Foam material, which can be additionally compressed. Two to three times compressed foam material with the designation "Jet 6" from the manufacturer Fritz Nauer AG, www.foampartner.com, was used successfully in prototypes. The liquid storage system just illustrated has the disadvantage that the cartridge 86 can be removed from the inhaler component 2. Of course, there are dangers associated with this, for example the danger that the relatively small cartridge 86 will be swallowed by small children. The liquid storage system is therefore not suitable for storing medicines and/or poisons such as nicotine.

Further, general components of the inhaler according to the invention are to be described in more detail below, which components are present in all exemplary embodiments: how 6 , 9 and 19 show, the plate-shaped contacts 23 of the replaceable inhaler component 2 protrude from the outer surface of the housing 3 in the form of two plug-in contacts 93 . The plug contacts 93 form electrical contacts with corresponding spring contacts 94 in the course of the coupling of the inhaler component 2 to the inhaler part 1 , via which electrical energy for evaporating the liquid material 16 is supplied to the heating element. The spring contacts 94 are part of the contact elements 20 and preferably by a welded connection this connected - see also Figures 4-5 . The contact elements 20 preferably consist of a metallic contact material and can be manufactured, for example, by Ami Doduco GmbH, www.amidoduco.com. If, for the reasons already mentioned, the same or a similar material is used for the plate-shaped contacts 23 as for the heating element - e.g For example, galvanically coated with a conductive layer of gold, silver, palladium and / or nickel, whereby the electrical contact resistance is significantly reduced. The contact elements 20 obtain the electrical energy via two wires 95 which connect the contact elements 20 to the circuit board 11 - see Figures 4-5 . The wires 95 are preferably attached on both sides by soldering. In summary, it should again be pointed out that the contact elements 20 fulfill up to three different tasks: First, they transfer, as just described above, the electrical energy from the circuit board 11 to the plate-shaped contacts 23. Second, they form lateral locking lugs 9, which with the Snap hooks 8 of the housing 3 interact, as a result of which the snap connection between the inhaler component 2 and the inhaler part 1 is realized. And thirdly, one of the two contact elements 20 forms a stop for the pin 46, as a result of which the ram-like operative connection to the opening of the liquid container 4 is established. The latter task appears only in one embodiment variant of the inhaler and its liquid container system.

For coupling the inhaler component 2 to the inhaler part 1 in a precise position, a positioning device is provided which consists of a centering projection 96 arranged on the carrier housing 10 and a centering recess 97 corresponding thereto and arranged on the housing 3 - see 3 , 6 , 10 and 12 . The centering projection 96 has two vent holes 98 which vent the centering recess 97 in the course of the coupling.

29 1 shows an exchangeable inhaler component 2 of an inhaler according to the invention, which differs from the inhaler components described above in that it has two flat composites 22a and 22b arranged next to one another. The flat composites 22a and 22b can, for example, have a structure as already described in FIGS Figures 14-15 has been described in detail. The flat composites 22a and 22b or their heating resistors are electrically connected to one another in series. The series connection has the effect that the resulting heating resistance doubles with an unchanged composite span, if the individual resistances of the composites 22a and 22b are of the same magnitude. The beneficial effects of this increase in resistance have been discussed previously. In principle, the heating resistance of the composite could also be increased by increasing the composite span. However, this would have a very adverse effect on the infiltration time, that is the time required for the liquid material 16 to completely re-infiltrate the wick after evaporation. The infiltration time would increase by leaps and bounds. Assuming the composite specifications in Table 1 as an example, and connecting two composites 22a and 22b with a composite width of 4mm each and an etching rate of 25% in series, this results in a heating element resistance of about 275mOhm. With this resistance value, it makes sense to further reduce the composite span with regard to a short infiltration period, eg to 12mm, which would reduce the heating element resistance to a value of around 235mOhm. The two composites 22a and 22b can optionally also have different resistance values, which can be implemented most simply by assigning different composite widths to the two composites. In this way, the evaporation process can be spatially varied. Furthermore, the two composites 22a and 22b can optionally be fed from different sources of liquid material. By means of the last two configuration options, it is possible to influence the aerosol formation process and ultimately the properties of the condensation aerosol formed in an even more targeted manner. In this way, for example, the vaporization process in the distillation zone of a cigarette can be approximately simulated spatially and temporally.

The composites 22a and 22b in turn rest with their end sections on electrically conductive, plate-shaped contacts, and their heating elements are electrically contacted with the contacts. Unlike the earlier described embodiments, the plate-shaped contacts are in two on one side Contact parts 23a and 23b split, which are electrically isolated from each other. The first planar composite 22a rests with an end section on the contact part 23a, and the second planar composite 22b rests with an end section on the contact part 23b. On the opposite side, the two composites 22a and 22b rest with their end sections on a common plate-shaped contact 23c. The plate-shaped contact 23c electrically connects the two composites 22a and 22b to one another. The plate-shaped contact 23c brings about the actual electrical series connection, while the electrical energy is fed to the connections 22a and 22b via the contact parts 23a and 23b. The electrical coupling to the reusable inhaler part 1 is again effected via the plug-in contacts 93, the arrangement of which is identical to the coupling scheme of the previously illustrated exemplary embodiments, cf. 6 , 9 and 19 . In order to be able to retain this coupling scheme, the contact part 23a is designed in the specific exemplary embodiment in such a way that it extends transversely through the housing 3 to the opposite side of the inhaler component 2 via a connecting web 110 . How 29 shows, the connecting web 110 runs below the slot-shaped channel 26. Instead of the connecting web 110, a wire could alternatively also establish the electrical connection. Alternatively, it would also be possible to lead the two plug contacts 93 out of the housing on the same side of the housing, with the obvious choice here being the side on which the contact parts 23a and 23b are also arranged. Finally, it should also be mentioned that the plate-shaped contacts or contact parts 23a, 23b and 23c can also be formed by printed circuit boards or a single common printed circuit board. Thick copper printed circuit boards with a copper layer thickness in the range of 100-500 µm are preferred because of the better heat dissipation. Good heat dissipation must be ensured above all in the area of the capillary gap 41 in order to prevent the liquid material 16 from boiling in the capillary gap 41 .

The sensor 99, 100 forms an essential part of the inhaler according to the invention—see FIG 8 , 18 as well as 21-22 . The sensor 99, 100 has the task of detecting the beginning of a puff or an inhalation, whereupon the electrical circuit 11 activates the supply of electrical energy to the heating element of the assembly 22, 39, and the evaporation of the liquid material 16 begins. There can be at least two different types of sensors be used: in the embodiment according to 8 , the sensor consists of a pressure sensor 99. The pressure sensor 99 is glued into the carrier housing 10 and its electrical connections or pins 101 are soldered directly to the circuit board 11. The pressure sensor 99 communicates with the plenum chamber 27 via a bore 102 and measures or monitors the negative pressure in the plenum chamber 27 - see FIG 18 . A suitable pressure sensor 99 is, for example, the type CPCL04GC from the manufacturer Honeywell Inc., www.honeywell.com, with a measuring range of +/-10 mbar. The sensor mentioned essentially consists of a zero-point calibrated and temperature-compensated measuring bridge and can be wired as follows on circuit board 11: the negative sensor output is grounded via a high-impedance resistor with a defined resistance value - e.g. 2.2 MOhm, whereby the Output or measurement signal of the pressure sensor 99 is slightly distorted, or to put it another way, the offset of the measuring bridge is calibrated to a defined value. A switching threshold is specified by the distortion or by the offset, which corresponds to a specific pressure threshold value. The measurement signal processed in this way is applied to the input of a precision operational amplifier 103 connected as a comparator, eg of the type LTC1049CS8 from the manufacturer Linear Technology Inc., www.linear.com. This wiring results in an output signal that shows the start of the train in digital form extremely quickly and precisely. The pressure sensor 99 is particularly suitable for use in draw-in inhalers if a flow restrictor 28 is arranged upstream of the plenum chamber 27 . In this case, in relation to the environment, a negative pressure occurs in the plenum chamber 27 in the course of a train, which is typically in the range of 0-50 mbar. The pressure curve is approximately bell-shaped. The beginning of the train can be detected in a simple manner by specifying a pressure threshold value, as described above, which is constantly compared with the actually measured pressure. The start of traction can be defined as the first time the pressure threshold is exceeded. A value in the range of 0.2-5 mbar is expediently selected for the pressure threshold value. The smaller the selected pressure threshold value, the faster the train detection responds. A lower limit is set by the specifications of the particular pressure sensor and operational amplifier used.

If no flow restrictor 28 is provided in the inhaler, the pressure in the plenum chamber 27 is practically ambient. These conditions are in the embodiment after 21-22 given. The classic inhaler shown operates under near-atmospheric pressure conditions and allows direct lung inhalation in a single step. In this case, it is more expedient to use a flow sensor 100 to detect the start of inhalation. The flow sensor 100 is in the embodiment according to 21-22 arranged in the transverse channel 29, and its connections or pins 101 are soldered directly to the circuit board 11 again. A thermistor 100, for example of the type GR015 from the manufacturer Betatherm Corporation, www.betatherm.com, is preferably suitable as the flow sensor 100. The thermistor 100 is connected to a measuring bridge (not shown) on the printed circuit board 11 . The measuring bridge contains a second thermistor of the same type for temperature compensation and is calibrated to a defined offset threshold value using precision resistors. The output signal of the measuring bridge is then applied to the input of an operational amplifier 103 connected as a comparator. In the equilibrium state, the two thermistors are at the same temperature level - typically in the range of 80-200°C, depending on the power dissipated. As soon as a user starts inhaling, air flows through the transverse channel 29. The air cools the thermistor 100, which increases its resistance. The change in resistance is processed by the measuring bridge. At the moment when the output signal of the measuring bridge crosses the zero point, the comparator 103 changes over and emits a digital signal characterizing the start of inhalation.

The further processing of the signals output by the sensors 99, 100 and their wiring preferably takes place in an integrated circuit 104--see FIG 8 and 21 . The integrated circuit 104 can also be a microprocessor. The integrated circuit 104 processes a large part of all electrical signals from the inhaler and carries out the control operations which are essential for the operation of the inhaler. These control operations will be explained in more detail below: a central control operation is the supply of electrical energy to the heating element of the assembly 22, 39. The electrical energy is supplied by the energy store 12. Lithium polymer and lithium ion cells are available based on the current state of the art due to its high energy and power density in a special way as an energy store 12. In the case of metallic heating elements, a single lithium polymer or lithium ion cell with an open circuit or nominal voltage of around 3.7V is sufficient. The energy and power supply to the heating element of the assembly 22, 39 can be regulated in a simple manner by the battery voltage being chopped up over the duration of the energy supply with a variable degree of modulation and the resulting useful voltage being applied to the heating element. The resulting useful voltage is a square-wave signal with a variable duty cycle. The amplitude of the square-wave signal corresponds to the battery voltage, disregarding minor voltage losses. The actual chopping preferably takes place by means of a power MOSFET 105, for example of the type IRF6635 from the manufacturer International Rectifier, www.irf.com, which is suitable for switching very high currents with a minimal drain-source on-resistance. The integrated circuit 104 controls the gate of the power MOSFET 105. A very simple control strategy, which has also proven itself in prototypes according to the invention, consists in dividing the duration of the energy supply into two periods—into a heating-up period and a subsequent one evaporation period. In the intermittent, inhalation or puff-synchronous operation of the inhaler, the duration of the energy supply is based on the duration of a puff or an inhalation. In the case of draw inhalers, for example, an average draw duration of around 2.1 seconds (+/-0.4 seconds) can be assumed. The same value applies roughly to cigarettes. If one considers that even after the energy supply has been switched off, post-evaporation takes place to a certain extent because of the heat still stored in the assembly 22, 39, it seems advisable to select the duration of the energy supply somewhat shorter, eg a value in the range 1.5-1 ,8sec. With classic inhalers, it can be advantageous to further reduce the duration of the energy supply in order to achieve a high degree of alveolar drug absorption. In comparison to classic inhalers, draw-in inhalers have the advantage that the drug is, so to speak, at the forefront of the column of air inhaled into the lungs, which means that the drug can penetrate more easily to the alveoli. In contrast, with classic inhalers, the drug goes directly into the inhaled column of air. Here it must be taken into account that an end section of the inhaled air column only serves to fill the so-called "functional dead space" (approx. 150-200mL) of the breathing system. In any case, portions of the drug in this dead space no longer reach the alveoli and are therefore lost for rapid systemic action. If one also considers that the duration of inhalation varies greatly between individuals, namely between about 1.5-3 seconds, it seems appropriate to choose a value of <1.5 seconds for the duration of the energy supply in classic inhalers. During the first of the two periods mentioned above--the heating-up period--the composite 22, 39, together with the liquid material 16 stored in the wick, is heated by the heating element. The evaporation of the liquid material 16 only begins when the temperature of the composite 22, 39 has reached approximately the boiling range of the low-boiling fractions of the liquid material 16. The heating-up period should therefore be as short as possible. In this respect, it makes sense to pass on the battery voltage to the heating element uninterrupted or with a modulation level or duty cycle of 100% during this period. The duration of the heating-up period depends above all on the specifications of the composite 22, 39 and on the quantity and composition of the liquid material 16 to be evaporated and should be <0.5 seconds if possible. In the subsequent second period--the evaporation period--the degree of control is significantly reduced and the actual evaporation of the liquid material 16 takes place. The energy supplied is used in this second period primarily for evaporating the liquid material 16 and secondarily for covering energy losses. By appropriately selecting the degree of control, the evaporation capacity and thus also the quantity of the liquid material 16 evaporated per puff or inhalation can be controlled within certain limits. An upper limit is set by the occurrence of a boiling crisis and by local drying out and overheating of the wick. On the other hand, thermal decomposition of the liquid material 16 can be counteracted by reducing or throttling the degree of modulation.

The control strategy just described can be expanded and refined as desired: for example, it can make sense to also take the state of the battery into account in the control strategy, since the battery voltage drops significantly as the battery discharges and ages, especially under load. This effect can be counteracted by increasing the modulation level become. In order to be able to carry out this correction during the warm-up period as well, it is expedient not to control the battery voltage of a new, charged battery to 100%, as previously suggested, but only to 80%, so that there is still enough leeway for an adjustment.

The control of the energy supply to the heating element of the assembly 22, 39 also requires various auxiliary operations: for example, it must be provided that the energy supply cannot be activated again immediately after the end of an evaporation cycle. Rather, a waiting time must be observed, which allows the liquid material 16 enough time to completely infiltrate the wick again. The minimum required waiting time depends on the respective specifications of the composite and on the viscosity of the liquid material. It could be shown in prototypes and calculations confirm that with an appropriate design a complete infiltration of the wick can be achieved in less than 10 seconds. A mandatory waiting time of this magnitude should be tolerated by most users, especially considering that in the case of the cigarette, the interval between two puffs averages 25 seconds. Such a waiting time must also be observed after a new inhaler component 2 has been coupled to the inhaler part 1 . Another auxiliary operation is that if the user prematurely terminates the puff or inhalation, the power to the heating element is immediately terminated. In this way it is prevented that steam is formed in the chamber 21 unnecessarily.

Another control operation of the integrated circuit 104 relates to the user interface, ie the communication with the user. The sensor 99, 100 for detecting the start of puffing or inhalation represents an input interface and is indispensable as such. In a very simple configuration of the user interface, no further input interface is provided, not even an on/off switch, as a result of which the use of the inhaler is extremely uncomplicated. The omission of an on-off switch naturally presupposes that the electrical circuit 11 requires a correspondingly small amount of power, which must be taken into account when creating the circuit diagram. For example, it can be provided that the switching circuit 11 switches to a particularly energy-saving sleep mode as long as no inhaler component 2 is coupled to the inhaler part 1 . As For example, two light-emitting diodes 106 can be used as output interfaces, the first of which indicates the state of charge of the battery 12 and the second of which signals the forthcoming change interval of the inhaler component 2 . The change interval of the inhaler component 2 can be monitored by a counter which also counts the number of puffs or inhalations. In the course of replacing the inhaler component 2, the counter is reset to zero (reset), it being possible to take advantage of the fact that the heating element resistance becomes infinitely large for a moment. In a somewhat more complex embodiment, a display (not shown) can be integrated into the circuit cover 7 instead of the light-emitting diodes 106 . In addition to the battery charge level and the imminent change of the inhaler component 2, the display can also show other operating states and information, for example the total drug dose delivered over a specific period of time. In the case of nicotine, the degree of nicotine dependence of the user can be determined very objectively in this way, and the success actually achieved in the course of a gradual cessation. Finally, the display can support the user in operating the inhaler in the form of user guidance. An acoustic, vibratory and/or visual alarm can also be provided as an output interface, which supports the user in administering the respective drug at the right time and in the required dosage. Finally, a data interface, for example in the form of a USB or Bluetooth interface, can also be provided, via which firmware and software updates in particular can be loaded, diagnostic functions can be carried out and information, in particular relating to the administered drug dose, can be read out. By means of the latter function, a treating doctor can record and evaluate the drug dose administered over a longer period of time and its course over time exactly and objectively, and adjust his medical treatment accordingly.

A further control operation, which can optionally be provided, relates to the identification of the inhaler component 2 used, the identification of the user and, in connection therewith, the detection of improper use of the inhaler. The identification of the inhaler component 2 together with the type of composite and liquid material 16 contained in it can be carried out in a simple manner by measuring the resistance of the heating element take place. However, there are certain limits to this method, because each drug preparation must be assigned a specific type of composite with a defined heating element resistance. A somewhat more complex method consists in arranging an identification chip (not shown) in the inhaler component 2 which uniquely identifies the inhaler component 2 . With the help of such a chip, it is possible to uniquely identify each individual inhaler component 2 that is produced and sold. The chip is preferably arranged on one of the two plate-shaped contacts 23, it being particularly favorable if the plate-shaped contact 23 is formed by a printed circuit board. The information stored in the chip is read out by the integrated circuit 104, which in this case preferably consists of a microprocessor. On the basis of the information read out, the microprocessor 104 selects the operating parameters suitable for the inhaler component 2 used. Furthermore, the microprocessor 104 can block the respective inhaler component 2 after the change interval has been reached or render it unusable by suitable means, so that no further puffs or inhalations can be carried out with this inhaler component 2 . This measure serves primarily to avoid misuse of the inhaler component 2. Such misuse would occur, for example, if a user tries to continue using the inhaler component 2 beyond the change interval, for example by forcibly opening the liquid container 4 and even liquid material 16 refills. In the case of nicotine, the lethal dose (LD50) is around 0.5-1.0 mg/kg body weight. One can roughly imagine how dangerous such abuse would be for the user and his environment. The risk of such misuse and the risk to the environment from used, discarded inhaler components 2 can be further reduced by selling the inhaler component 2 according to the deposit system. The identification of the user serves to prevent the inhaler from being used by unauthorized third parties and in this way also prevents theft. The user can be identified, for example, via a touch display by entering a code, or biometrically using a fingerprint.

Another control operation that can be performed by the integrated circuit 104 relates to the cell and charge management of the battery 12.

Since integrated circuits are already available on the market for this purpose, this control operation can alternatively also take place in a separate integrated circuit. The charging current is supplied via the charging plug 107, which is arranged on the end face of the inhaler part 1 facing away from the mouthpiece 5—see FIG 3 and 8 . The charging plug 107 can also be a diagnostic plug, via which the electrical circuit 11 and the heating element resistance of the assembly 22, 39 can be checked using an external analysis device and possible faults can be identified.

The implementation of the control operations described above in a circuit diagram can be performed by any person skilled in this field using known methods, and is therefore not to be described further in this context.

Finally, the function and mode of operation of the inhaler according to the invention is explained in summary again: the user makes a new inhaler component 2 ready for use by coupling it to the reusable inhaler part 1 via the snap connection 8, 9. The liquid container 4 is opened in the exemplary embodiment according to FIG 6 synchronously with the coupling to the inhaler part 1 by means of the pin 46 in cooperation with the contact element 20 (see 19 ). In contrast, the opening of the liquid container 4 takes place in the exemplary embodiment Figures 24a and 24b characterized in that the user moves the liquid container 4 into the housing 3 (see arrow direction). In both cases, an extension 44 ( 19 ) or as the first mandrel 81 ( 25 ) formed end of the capillary gap 41 wetted with the liquid material 16. The capillary gap 41 exerts a capillary force on the wetting liquid material 16, which causes the capillary gap 41 to be rapidly flooded. The liquid material 16 reaches the composite 22, 39 (see 11 ). The composite 22, 39 consists of a wick and an electrical heating element. The capillary forces in the wick cause it to be quickly infiltrated by the liquid material 16 as well. At the same time, the buffer store 53 consisting of capillaries 54 is also flooded with the liquid material 16 . The buffer store 53 enables the inhaler to be operated in any position. The time between the opening of the liquid container 4 and the complete infiltration of the wick corresponds to an obligatory waiting time for the user and is in any case less than 10 seconds if the design is appropriate. The inhaler is now operational. The user leads over the mouthpiece 5 in the case of a draw inhaler according to the invention ( Figures 9-10 ) a puff similar to that of a cigarette, and in the case of a classic inhaler according to the invention ( 21-22 ) a direct lung inhalation. The sensor 99,100 ( 8 and 21 ) detects the beginning of the puff or the inhalation and causes the integrated circuit 104 to supply the heating element of the assembly 22, 39 with electrical energy according to a predetermined control strategy. This means that the composite 22, 39 heats up in a flash and the liquid material 16 in the wick evaporates. The vapor formed leaves the composite 22, 39 via the wick surface which is exposed in large areas of the composite and mixes in the chamber 21 with the air flowing into the chamber 21 through the air inlet opening 26. Mixing with the air, the vapor cools and forms a condensation aerosol ( Figures 9-10 and 21-22 ). Excess condensate, which does not contribute to the formation of the condensation aerosol or vapor-air mixture, is sucked up and bound by sponges 57 arranged in the chamber 21 . In the embodiment after Figures 9-10 (puff inhaler), the vapor-air mixture formed and/or condensation aerosol flows through the filling material 61 to improve its organoleptic properties before it finally reaches the user's oral cavity via the mouthpiece channel 66 . In the embodiment after 21-22 (classic inhaler), the vapor-air mixture formed and/or condensation aerosol exits the chamber 21 through the orifice opening 71 formed by the vanes 69 and combines with the bypass air flowing in through the bypass openings 68, finally, after flowing through a mouthpiece channel 66 optionally arranged flow homogenizer 72 also to get into the oral cavity of the user. After waiting a few seconds, the liquid material 16 has completely infiltrated the wick of the assembly 22, 39 again and the inhaler is ready for another inhalation. If the liquid container 4 contains, for example, 2.5 mL of effectively usable liquid material 16, and if the liquid material contains nicotine as a drug in a concentration of typically 1.5% by volume, then up to 380 puffs or inhalations can be carried out with such an inhaler component. if 100 µg of nicotine are vaporized per inhalation. 380 puffs correspond to about 38 cigarettes. If only 50 pg of nicotine is vaporized per inhalation, then it increases the range to 760 inhalations, which corresponds to around four packs of cigarettes.

Finally, on the basis of the drug nicotine, an exemplary preparation of the liquid material 16 is to be disclosed, which was vaporized in prototypes according to the invention designed as inhalers. The condensation aerosol formed and administered in this way came very close to the smoke of a conventional cigarette in terms of pharmacological, pharmacokinetic and organoleptic effects. All listed ingredients are also found in cigarette smoke. <u>Table 2:</u> Exemplary drug preparation based on nicotine Material CAS number mass % ethanol 64-17-5 68.80 Water 7732-18-5 16.50 glycerol 56-81-5 9.10 nicotine 54-11-5 1.80 lactic acid 50-21-5 0.23 succinic acid 110-15-6 0.28 levulinic acid 123-76-2 0.46 benzoic acid 65-85-0 0.08 phenylacetic acid 103-82-2 0.08 acetic acid 64-19-7 1.67 formic acid 64-18-6 0.53 propionic acid 79-09-4 0.27 Solanon 1937-54-8 0.05 tobacco flavor oils ^∗ ) 0.15 ambroxide 6790-58-5 optional menthol 2216-51-5 optional Total: 100.00 ^∗ ) Tobacco flavor oils obtained by supercritical CO2 extraction; eg tobacco extracts from Pro-Chem Specialty Limited, Hong Kong, www.pro-chem-specialty.com, eg product no. SF8010, SF8011 or SF208118; or according to patent publication no. DE19654945A1 , DE19630619A1 , DE3218760A1 , DE3148335A1 (Adam Müller et al. ) manufactured tobacco flavor oils; A prerequisite for the use of such tobacco aroma oils in the nicotine solution is that they are as free as possible of tobacco-specific nitrosamines (TSNA).

For the sake of completeness, it should also be noted that additional functions can be integrated into the inhaler according to the invention, which go beyond the actual task of the inhaler and expand the inhaler into a multifunction device or hybrid device. Such functions can be, for example: clock, mobile data storage, player functions (including dictation function), PDA functions, navigation aid (GPS), mobile telephony and photography.

Reference List

1

inhaler part

2

inhaler component

3

Housing

4

liquid container

5

mouthpiece

6

battery cover

7

circuit cover

8th

snap hook

9

detent

10

carrier housing

11

electrical circuit, circuit board

12

energy storage; battery

13

partition wall

14

flat contact

15

Window

16

liquid material; Drug Preparation

17

filling hole

18

openable closure

19

cap

20

contact element

21

chamber

22

flat bond

23

plate contact

24

first side of the flat bond

25

second side of the flat bond

26

air intake opening; slotted channel

27

plenum chamber

28

flow restrictor

29

cross channel

30

feed opening

31

Foil; metal foil

32

Tissue; metal wire mesh

33

open-pored fiber structure; fleece

34

open-pored sintered structure; granular, fibrous or flaky sintered composite

35

Channel; artery

36

Hole

37

open cell foam

38

backing layer

39

linear compound

40

ram

41

capillary gap

42

top

43

plate

44

extension

45

reservoir

46

Pen

47

first end

48

second end

49

material weakening

50

hinge

51

cross-sectional enlargement

52

ventilation duct!

53

buffer storage

54

Capillary; slot

55

opening

56

ventilation gap

57

porous, absorbent body; sponge

58

flow channel

59

wall section

60

gap

61

Cooler; Filling material; tobacco filling

62

filling space

63

perforated wall

64

first wire mesh

65

second wire mesh

66

mouthpiece channel

67

collection chamber

68

bypass opening

69

vane

70

vane tip

71

muzzle opening

72

flow homogenizer

73

non-releasable blocking device; head Start

74

cones

75

groove

76

vent hole

77

ventilation channel

78

first opening

79

second opening

80

foil seal

81

first thorn

82

second thorn

83

micro bridge

84

liquid storage; open cell foam

85

cartridge case

86

cartridge

87

recess

88

Lid

89

snap connection

90

elevation

91

ventilation hole

92

recess

93

plug contact

94

spring contact

95

wire

96

centering projection

97

centering recess

98

vent hole

99

pressure sensor

100

Flow sensor, thermistor

101

electrical connection; Pin code

102

drilling

103

operational amplifiers; comparator

104

integrated circuit; microprocessor

105

Power MOSFET

106

led

107

charging plug

108

recess

109

locking plate

110

connecting bar

1. 1. Inhalatorkomponente für die intermittierende, inhalations- oder zugsynchrone Bildung eines Dampf-Luft-Gemisches oder/und Kondensationsaerosols, umfassend:
   • ein Gehäuse (3);
   • eine im Gehäuse (3) angeordnete Kammer (21);
   • eine Lufteinlaßöffnung (26) für die Zufuhr von Luft aus der Umgebung in die Kammer (21);
   • ein elektrisches Heizelement zur Verdampfung einer Portion eines flüssigen Materials (16), wobei der gebildete Dampf sich in der Kammer (21) mit der durch die Lufteinlaßöffnung (26) zugeführten Luft mischt, und sich das Dampf-LuftGemisch oder/und Kondensationsaerosol bildet;
   • und einen Docht mit einer Kapillarstruktur, welcher Docht mit dem Heizelement einen Verbund (22) bildet und das Heizelement nach einer Verdampfung von neuem selbsttätig mit dem flüssigen Material (16) versorgt,
   • dadurch gekennzeichnet, daß der Verbund (22) flächig ausgebildet ist, und zumindest ein beheizter Abschnitt des Verbundes (22) berührungsfrei in der Kammer (21) angeordnet ist, und die Kapillarstruktur des Dochts im besagten Abschnitt wenigstens auf einer Seite (24) des flächigen Verbundes weitgehend freiliegt.
2. 2. Inhalatorkomponente nach Aspekt 1, dadurch gekennzeichnet, daß die Kapillarstruktur des Dochts im besagten Abschitt auf beiden Seiten (24, 25) des flächigen Verbundes (22) weitgehend freiliegt.
3. 3. Inhalatorkomponente nach Aspekt 1 oder 2, dadurch gekennzeichnet, daß der Verbund (22) eine Dicke kleiner als 0,6mm aufweist.
4. 4. Inhalatorkomponente nach Aspekt 1 oder 2, dadurch gekennzeichnet, daß der Verbund (22) eine Dicke kleiner als 0,3mm aufweist.
5. 5. Inhalatorkomponente nach einem der Aspekte 1-4, dadurch gekennzeichnet, daß der Verbund (22) plattenförmig, folienförmig, streifenförmig oder bandförmig ausgebildet ist.
6. 6. Inhalatorkomponente nach einem der Aspekte 1-5, dadurch gekennzeichnet, daß der Verbund (22) eine der folgenden Strukturen enthält: Gewebe, offenporige Faserstruktur, offenporige Sinterstruktur, offenporiger Schaum, offenporige Abscheidungsstruktur.
7. 7. Inhalatorkomponente nach einem der Aspekte 1-5, dadurch gekennzeichnet, daß der Verbund (22) mindestens zwei Lagen aufweist.
8. 8. Inhalatorkomponente nach Aspekt 7, dadurch gekennzeichnet, daß die Lagen mindestens eine der folgenden Strukturen enthalten: Platte, Folie (31), Papier, Gewebe (32), offenporige Faserstruktur (33), offenporige Sinterstruktur (34), offenporiger Schaum (37), offenporige Abscheidungsstruktur.
9. 9. Inhalatorkomponente nach Aspekt 8, dadurch gekennzeichnet, daß die Lagen durch eine Wärmebehandlung miteinander verbunden sind.
10. 10. Inhalatorkomponente für die intermittierende, inhalations- oder zugsynchrone Bildung eines Dampf-Luft-Gemisches oder/und Kondensationsaerosols, umfassend:
    • ein Gehäuse (3);
    • eine im Gehäuse (3) angeordnete Kammer (21);
    • eine Lufteinlaßöffnung (26) für die Zufuhr von Luft aus der Umgebung in die Kammer (21);
    • ein elektrisches Heizelement zur Verdampfung einer Portion eines flüssigen Materials (16), wobei der gebildete Dampf sich in der Kammer (21) mit der durch die Lufteinlaßöffnung (26) zugeführten Luft mischt, und sich das Dampf-LuftGemisch oder/und Kondensationsaerosol bildet;
    • und einen Docht mit einer Kapillarstruktur, welcher Docht mit dem Heizelement einen Verbund (39) bildet und das Heizelement nach einer Verdampfung von neuem selbsttätig mit dem flüssigen Material (16) versorgt,
    • dadurch gekennzeichnet, daß der Verbund (39) linienförmig ausgebildet ist, und zumindest ein beheizter Abschnitt des Verbundes berührungsfrei in der Kammer (21) angeordnet ist, und die Kapillarstruktur des Dochts im besagten Abschnitt weitgehend freiliegt.
11. 11. Inhalatorkomponente nach Aspekt 10, dadurch gekennzeichnet, daß der Verbund eine Dicke kleiner als 1,0mm aufweist.
12. 12. Inhalatorkomponente nach Aspekt 10 oder 11, dadurch gekennzeichnet, daß der Verbund mindestens eine der folgenden Strukturen enthält: Draht, Garn, offenporige Sinterstruktur (34), offenporiger Schaum, offenporige Abscheidungsstruktur.
13. 13. Inhalatorkomponente nach einem der Aspekte 1-12, dadurch gekennzeichnet, daß das Heizelement zumindest teilweise in den Docht integriert ist.
14. 14. Inhalatorkomponente nach Aspekt 13, dadurch gekennzeichnet, daß der Docht zumindest teilweise aus einem elektrischen Widerstandsmaterial besteht.
15. 15. Inhalatorkomponente nach Aspekt 14, dadurch gekennzeichnet, daß das elektrische Widerstandsmaterial metallisch ist.
16. 16. Inhalatorkomponente nach einem der Aspekte 1-15, dadurch gekennzeichnet, daß die Verbindung zwischen dem Heizelement und dem Docht sich über die gesamte Ausdehnung des Dochts erstreckt.
17. 17. Inhalatorkomponente nach einem der Aspekte 1-16, dadurch gekennzeichnet, daß der Verbund (22, 39) geätzt ist.
18. 18. Inhalatorkomponente nach einem der Aspekte 1-17, dadurch gekennzeichnet, daß die Oberfäche des Verbundes (22, 39) aktiviert ist.
19. 19. Inhalatorkomponente nach einem der Aspekte 1-18, dadurch gekennzeichnet, daß der Docht als arterieller Docht ausgebildet ist.
20. 20. Inhalatorkomponente nach einem der Aspekte 1-19, dadurch gekennzeichnet, daß der Docht in Dickenrichtung gelocht ist.
21. 21. Inhalatorkomponente nach einem der Aspekte 1-5, dadurch gekennzeichnet, daß der flächige Verbund (22) im Wesentlichen plan ausgebildet ist, und die Lufteinlaßöffnung als schlitzförmiger Kanal (26) ausgebildet ist, und der schlitzförmige Kanal (26) parallel zur planen Verbundfläche ausgerichtet ist.
22. 22. Inhalatorkomponente nach Aspekt 10 oder 11, dadurch gekennzeichnet, daß der linienförmige Verbund (39) im Wesentlichen geradlinig ausgebildet ist, und die Lufteinlaßöffnung als schlitzförmiger Kanal (26) ausgebildet ist, und der schlitzförmige Kanal (26) parallel zum geradlinigen Verbund (39) ausgerichtet ist.
23. 23. Inhalatorkomponente nach einem der Aspekte 1-22, dadurch gekennzeichnet, daß der Verbund (22, 39) die Kammer (21) brückenartig durchsetzt und mit zwei Endabschnitten auf zwei elektrisch leitenden, plattenförmigen Kontakten (23) lagert, und das Heizelement mit den Kontakten (23) elektrisch kontaktiert ist.
24. 24. Inhalatorkomponente nach Aspekt 23, dadurch gekennzeichnet, daß die elektrische Kontaktierung des Heizelements aus einer Schweiß- oder Sinterungverbindung besteht.
25. 25. Inhalatorkomponente nach Aspekt 23, dadurch gekennzeichnet, daß daß die elektrische Kontaktierung des Heizelements aus einer Klebeverbindung mittels eines elektrisch leitenden Klebstoffes besteht.
26. 26. Inhalatorkomponente nach Aspekt 23-25, dadurch gekennzeichnet, daß die plattenförmigen Kontakte (23) aus der äußeren Oberfläche des Gehäuses (3) in Form zweier Steckkontakte (93) herausragen.
27. 27. Inhalatorkomponente nach einem der Aspekte 1-25, dadurch gekennzeichnet, daß der Verbund (22, 39) mit einem Ende in einen Kapillarspalt (41) ragt, dessen Strömungswiderstand kleiner ist als der Strömungswiderstand des Dochts.
28. 28. Inhalatorkomponente nach Aspekt 27, dadurch gekennzeichnet, daß der Querschnitt des Kapillarspalts (41) größer als der Querschnitt des Verbundes (22, 39) ist.
29. 29. Inhalatorkomponente nach Aspekt 27 oder 28, dadurch gekennzeichnet, daß das Heizelement des Verbundes (22, 39) im Kapillarspalt (41) elektrisch kontaktiert ist.
30. 30. Inhalatorkomponente nach einem der Aspekte 27-29 mit einem im Gehäuse (3) angeordneten oder mit dem Gehäuse (3) verbundenen, das flüssige Material (16) enthaltenden Flüssigkeitsbehälter (4) samt einem öffenbaren Verschluß (18), dadurch gekennzeichnet, daß der Flüssigkeitsbehälter (4) aus dem Gehäuse (3) weder entnehmbar noch vom Gehäuse (3) trennbar ist, und das flüssige Material (16) im Flüssigkeitsbehälter (4) durch manuelles Öffnen des öffenbaren Verschlusses (18) mit dem Kapillarspalt (41) kapillar koppelbar ist.
31. 31. Inhalatorkomponente nach Aspekt 30, dadurch gekennzeichnet, daß der Flüssigkeitsbehälter (4) mit dem Gehäuse (3) starr und permanent verbunden ist, oder selbst einen Teil des Gehäuses (3) bildet.
32. 32. Inhalatorkomponente nach Aspekt 31, gekennzeichnet durch ein mit dem Kapillarspalt (41) kommunizierendes Reservoir (45), welches an den Flüssigkeitsbehälter (4) anschließt und von diesem durch den öffenbaren Verschluß (18) getrennt ist.
33. 33. Inhalatorkomponente nach Aspekt 32, gekennzeichnet durch einen im Gehäuse (3) axial verschiebbar gelagerten Stift (46), dessen erstes Ende (47) gegen den öffenbaren Verschluß (18) gerichtet ist, und dessen zweites Ende (48) bei geschlossenem Verschluss (18) aus der äußeren Oberfläche des Gehäuses (3) fortsatzartig herausragt.
34. 34. Inhalator, umfassend eine Inhalatorkomponente nach Aspekt 33 sowie ein wiederverwendbares Inhalatorteil (1), welches mit der Inhalatorkomponente (2) koppelbar ist, dadurch gekennzeichnet, daß das zweite Ende (48) des Stiftes mit dem wiederverwendbaren Inhalatorteil (1) während der Kopplung in einer stößelartigen Wirkverbindung steht.
35. 35. Inhalatorkomponente nach Aspekt 33, dadurch gekennzeichnet, daß das Reservoir (45) über einen Belüftungskanal (52) mit der Kammer (21) kommuniziert.
36. 36. Inhalatorkomponente nach Aspekt 30, dadurch gekennzeichnet, daß der Flüssigkeitsbehälter (4) im Gehäuse (3) längs einer Verschiebeachse Y zwischen zwei Anschlagpo sitionen manuell verschiebbar angeordnet ist, und der Flüssigkeitsbehälter (4) in der ersten Anschlagposition mit einer nicht entriegelbaren Blockiervorrichtung (73) zusammenwirkt, und der Flüssigkeitsbehälter (4) in der zweiten Anschlagposition mit einem den öffenbaren Verschluß (18) öffnenden Öffnungsmittel (81, 82) zusammenwirkt.
37. 37. Inhalatorkomponente nach Aspekt 36, dadurch gekennzeichnet, daß das Öffnungsmittel (81, 82) einen vom Kapillarspalt (41) ausgebildeten ersten Dorn (81) umfaßt, welcher den öffenbaren Verschluß (18) in der zweiten Anschlagposition durchdringt, wodurch die kapillare Kopplung mit dem flüssigen Material (16) hergestellt wird.
38. 38. Inhalatorkomponente nach Aspekt 37, gekennzeichnet durch einen Belüftungskanal (52), dessen erstes Ende mit der Kammer (21) kommuniziert, und dessen zweites Ende als zweiter Dorn (82) ausgebildet ist, welcher den öffenbaren Verschluß (18) in der zweiten Anschlagposition durchdringt.
39. 39. Inhalatorkomponente nach Aspekt 36, dadurch gekennzeichnet, daß die nicht entriegelbare Blockiervorrichtung aus einem Vorsprung (73) besteht, gegen den der Flüssigkeitsbehälter (4) in der ersten Anschlagposition stößt.
40. 40. Inhalatorkomponente nach einem der Aspekte 36-39, umfassend ein Mundstück (5) mit einem Mundstückkanal (66), durch welchen ein Benutzer das Dampf-Luft-Gemisch oder/und Kondensationsaerosol dargeboten erhält, dadurch gekennzeichnet, daß die Verschiebeachse Y zumindest annähernd parallel zur Mittelachse des Mundstückkanals (66) ausgerichtet ist, und der Flüssigkeitsbehälter (4) zumindest in der ersten Anschlagposition mit einem Endabschnitt seitlich neben dem Mundstück (5) aus dem Gehäuse (3) ragt.
41. 41. Inhalatorkomponente nach einem der Aspekte 27-33 und 35-40, gekennzeichnet durch einen Pufferspeicher (53), welcher mit dem Kapillarspalt (41) kommuniziert und selbst aus Kapillaren (54) besteht.
42. 42. Inhalatorkomponente nach Aspekt 23 mit einem aus einem elastischen, offenporigen Material bestehenden und mit dem flüssigen Material (16) getränkten Flüssigkeitsspeicher (84), dadurch gekennzeichnet, daß der Verbund (22, 39) sandwichartig zwischen einem der beiden plattenförmigen Kontakte (23) einerseits, und dem Flüssigkeitsspeicher (84) andererseits eingeklemmt ist, wodurch der Docht mit dem flüssigen Material (16) im Flüssigkeitsspeicher (84) kapillar gekoppelt wird.
43. 43. Inhalatorkomponente nach einem der Aspekte 1-23 mit einer Kondensatbindeeinrichtung zur Aufnahme und Speicherung von Kondensatrückständen, welche im Zuge der Erzeugung des Dampf-Luft-Gemisches oder/und Kondensationsaerosols gebildet werden, dadurch gekennzeichnet, daß die Kondensatbindeeinrichtung aus einem offenporigen, saugfähigen Körper (57) besteht, welcher beabstandet, aber in unmittelbarer Nähe zur im besagten Abschnitt freiliegenden Kapillarstruktur des Dochts angeordnet ist.
44. 44. Inhalatorkomponente nach Aspekt 43, dadurch gekennzeichnet, daß der offenporige, saugfähige Körper (57) die im besagten Abschnitt freiliegende Kapillarstruktur des Dochts direkt überdeckt.
45. 45. Inhalatorkomponente nach Aspekt 43 oder 44, dadurch gekennzeichnet, daß der offenporige, saugfähige Körper (57) zwei zueinander beabstandet angeordnete Teile oder Abschnitte umfaßt, und der Verbund (22, 39) zumindest abschnittsweise zwischen den beiden Teilen oder Abschnitten angeordnet ist.
46. 46. Inhalatorkomponente nach einem der Aspekte 43-45, dadurch gekennzeichnet, daß der offenporige, saugfähige Körper (57) in der Kammer (21) angeordnet ist und den überwiegenden Teil der Kammer (21) ausfüllt.
47. 47. Inhalatorkomponente nach einem der Aspekte 43-46, dadurch gekennzeichnet, daß der offenporige, saugfähige Körper (57) aus einem formbeständigen Material besteht, welches auch nach vollständiger Infiltration mit den Kondensatrückständen seine Form weitgehend beibehält.
48. 48. Inhalatorkomponente nach einem der Aspekte 43-47, dadurch gekennzeichnet, daß der offenporige, saugfähige Körper (57) vom Gehäuse (3) weitgehend umschlossen wird und mit dem Gehäuse (3) untrennbar verbunden ist.
49. 49. Inhalatorkomponente nach einem der Aspekte 43-48, gekennzeichnet durch eine zweistufige Kondensat-Abscheidevorrichtung, bestehend erstens aus dem offenporigen, saugfähigen Körper (57) und zweitens aus einem vom gebildeten Dampf-Luft-Gemisch oder/und Kondensationsaerosol durchströmbaren Kühler.
50. 50. Inhalatorkomponente nach Aspekt 49, dadurch gekennzeichnet, daß der Kühler (61) durch eine Tabakfüllung (61) gebildet wird.
51. 51. Inhalatorkomponente nach Aspekt 50, dadurch gekennzeichnet, daß das Volumen der Tabakfüllung (61) größer als 3cm3 ist.
52. 52. Inhalatorkomponente nach einem der Aspekte 1-23 mit einer von einem Mundstück (5) gebildeten Mundstücköffnung, welche mit der Kammer (21) kommuniziert, und durch welche ein Benutzer das Dampf-Luft-Gemisch oder/und Kondensationsaerosol dargeboten erhält, wobei sich im Zuge der Inhalation zwischen der Lufteinlaßöffnung (26) und der Mundstücköffnung eine Strömung in Richtung der Mundstücköffnung ausbildet, welche Strömung zumindest abschnittsweise den Verbund (22, 39) passiert, dadurch gekennzeichnet, daß stromabwärts vom Verbund (22, 39) mindestens eine Luft-Bypassöffnung (68) angeordnet ist, durch welche zusätzlich Luft aus der Umgebung in die Strömung eingespeist wird, und der wirksame Strömungsquerschnitt der Luft-Bypassöffnung (68) mindestens 0,5 cm2 beträgt.
53. 53. Inhalatorkomponente nach Aspekt 52, dadurch gekennzeichnet, daß die Luft-Bypassöffnung aus zwei Bypassöffnungen (68) besteht, welche in gegenüberliegenden Gehäuseabschnitten angeordnet sind.
54. 54. Inhalatorkomponente nach Aspekt 53, dadurch gekennzeichnet, daß an die beiden Bypassöffnungen (68) zwei Leitschaufeln (69) anschließen, welche in Richtung der Mundstücköffnung weisen und aufeinander zustreben, und deren freie Enden eine düsenförmige Mündungsöffnung (71) bilden, durch welche das gebildete Dampf-Luft-Gemisch oder/und Kondensationsaerosol aus der Kammer (21) ausströmt und sich anschließend mit der aus den Bypassöffnungen (68) einströmenden Luft mischt.
55. 55. Inhalatorkomponente nach Aspekt 52, dadurch gekennzeichnet, daß stromabwärts der Luft-Bypassöffnung (68) ein Strömungshomogenisator (72) angeordnet ist, dessen Strömungswiderstand kleiner als 1 mbar bei einem Luftdurchsatz von 250 mL/sec ist.
56. 56. Inhalatorkomponente nach einem der Aspekte 1-23, gekennzeichnet durch mehrere nebeneinander angeordnete Verbunde (39a, 39b, 39c) mit unterschiedlichen Wärmekapazitäten.
57. 57. Inhalatorkomponente nach einem der Aspekte 1-23, gekennzeichnet durch mehrere nebeneinander angeordnete Verbunde (39a, 39b, 39c) mit unterschiedlichen Heizelement-Eigenschaften.
58. 58. Inhalatorkomponente nach einem der Aspekte 1-23, gekennzeichnet durch mehrere nebeneinander angeordnete Verbunde mit unterschiedlich ansteuerbaren elektrischen Heizelementen.
59. 59. Inhalatorkomponente nach einem der Aspekte 1-23, dadurch gekennzeichnet, daß mehrere nebeneinander angeordnete Verbunde vorgesehen sind, und den Verbunden flüssige Materialen mit unterschiedlicher Zusammensetzung zur Verdampfung zugeordnet sind.
60. 60. Inhalatorkomponente nach einem der Aspekte 1-23 mit mehreren nebeneinander angeordneten Verbunden (22a, 22b), deren Heizelemente aus elektrischen Heizwiderständen bestehen, dadurch gekennzeichnet, daß die Heizwiderstände miteinander in Reihe geschaltet sind.
61. 61. Inhalator, umfassend eine Inhalatorkomponente (2) nach einem der Aspekte 1-33 und 35-60.

The registration includes the following aspects:

1. 1. Inhaler component for the intermittent formation of a vapour-air mixture and/or condensation aerosol, synchronous with inhalation or puff, comprising:
   • a housing (3);
   • a chamber (21) arranged in the housing (3);
   • an air inlet port (26) for admitting air from the environment into the chamber (21);
   • an electrical heating element for evaporating a portion of a liquid material (16), the vapor formed mixing in the chamber (21) with the air supplied through the air inlet opening (26) and forming the vapour-air mixture and/or condensation aerosol;
   • and a wick with a capillary structure, which wick forms a composite (22) with the heating element and automatically supplies the heating element again with the liquid material (16) after evaporation,
   • characterized in that the composite (22) is flat, and at least one heated section of the composite (22) is arranged without contact in the chamber (21), and the capillary structure of the wick in said section at least on one side (24) of the flat Composite is largely exposed.
2. 2. Inhaler component according to aspect 1, characterized in that the capillary structure of the wick is largely exposed in said section on both sides (24, 25) of the planar composite (22).
3. 3. Inhaler component according to aspect 1 or 2, characterized in that the composite (22) has a thickness of less than 0.6 mm.
4. 4. Inhaler component according to aspect 1 or 2, characterized in that the composite (22) has a thickness of less than 0.3 mm.
5. 5. Inhaler component according to one of aspects 1-4, characterized in that the composite (22) is plate-shaped, film-shaped, strip-shaped or band-shaped.
6. 6. Inhaler component according to one of aspects 1-5, characterized in that the composite (22) contains one of the following structures: fabric, open-pore fiber structure, open-pore sintered structure, open-pore foam, open-pore deposition structure.
7. 7. Inhaler component according to one of aspects 1-5, characterized in that the composite (22) has at least two layers.
8. 8. Inhaler component according to aspect 7, characterized in that the layers contain at least one of the following structures: plate, foil (31), paper, fabric (32), open-pored fiber structure (33), open-pored sintered structure (34), open-pored foam (37 ), open-pored deposition structure.
9. 9. Inhaler component according to aspect 8, characterized in that the layers are connected to one another by heat treatment.
10. 10. Inhaler component for the intermittent, inhalation or train-synchronous formation of a vapor-air mixture and/or condensation aerosol, comprising:
    • a housing (3);
    • a chamber (21) arranged in the housing (3);
    • an air inlet port (26) for admitting air from the environment into the chamber (21);
    • an electrical heating element for evaporating a portion of a liquid material (16), the vapor formed mixing in the chamber (21) with the air supplied through the air inlet opening (26) and forming the vapour-air mixture and/or condensation aerosol;
    • and a wick with a capillary structure, which wick forms a composite (39) with the heating element and automatically supplies the heating element again with the liquid material (16) after evaporation,
    • characterized in that the composite (39) is linear and at least one heated section of the composite is arranged without contact in the chamber (21) and the capillary structure of the wick is largely exposed in said section.
11. 11. Inhaler component according to aspect 10, characterized in that the composite has a thickness of less than 1.0 mm.
12. 12. Inhaler component according to aspect 10 or 11, characterized in that the composite contains at least one of the following structures: wire, yarn, open-pore sintered structure (34), open-pore foam, open-pore separation structure.
13. 13. Inhaler component according to one of aspects 1-12, characterized in that the heating element is at least partially integrated into the wick.
14. 14. Inhaler component according to aspect 13, characterized in that the wick consists at least partially of an electrically resistive material.
15. 15. Inhaler component according to aspect 14, characterized in that the electrical resistance material is metallic.
16. 16. Inhaler component according to one of aspects 1-15, characterized in that the connection between the heating element and the wick extends over the entire extent of the wick.
17. 17. Inhaler component according to one of aspects 1-16, characterized in that the composite (22, 39) is etched.
18. 18. Inhaler component according to one of aspects 1-17, characterized in that the surface of the composite (22, 39) is activated.
19. 19. Inhaler component according to one of aspects 1-18, characterized in that the wick is designed as an arterial wick.
20. 20. Inhaler component according to one of aspects 1-19, characterized in that the wick is perforated in the direction of thickness.
21. 21. Inhaler component according to one of aspects 1-5, characterized in that the planar composite (22) is essentially flat and the air inlet opening is designed as a slit-shaped channel (26), and the slit-shaped channel (26) parallel to the planar composite surface is aligned.
22. 22. Inhaler component according to aspect 10 or 11, characterized in that the linear composite (39) is essentially rectilinear, and the air inlet opening is configured as a slit-shaped channel (26), and the slit-shaped channel (26) runs parallel to the rectilinear composite (39 ) is aligned.
23. 23. Inhaler component according to one of aspects 1-22, characterized in that the composite (22, 39) passes through the chamber (21) in a bridge-like manner and is supported with two end sections on two electrically conductive, plate-shaped contacts (23), and the heating element with the Contacts (23) is electrically contacted.
24. 24. Inhaler component according to aspect 23, characterized in that the electrical contacting of the heating element consists of a welded or sintered connection.
25. 25. Inhaler component according to aspect 23, characterized in that the electrical contacting of the heating element consists of an adhesive connection by means of an electrically conductive adhesive.
26. 26. Inhaler component according to aspects 23-25, characterized in that the plate-shaped contacts (23) protrude from the outer surface of the housing (3) in the form of two plug contacts (93).
27. 27. Inhaler component according to one of aspects 1-25, characterized in that the composite (22, 39) protrudes with one end into a capillary gap (41) whose flow resistance is less than the flow resistance of the wick.
28. 28. Inhaler component according to aspect 27, characterized in that the cross section of the capillary gap (41) is larger than the cross section of the composite (22, 39).
29. 29. Inhaler component according to aspect 27 or 28, characterized in that the heating element of the assembly (22, 39) is electrically contacted in the capillary gap (41).
30. 30. Inhaler component according to one of aspects 27-29 with a liquid container (4) containing the liquid material (16) which is arranged in the housing (3) or connected to the housing (3) and has an openable closure (18), characterized in that the liquid container (4) can neither be removed nor separated from the housing (3) and the liquid material (16) in the liquid container (4) is capillary by manually opening the openable closure (18) with the capillary gap (41). can be coupled.
31. 31. Inhaler component according to aspect 30, characterized in that the liquid container (4) is rigidly and permanently connected to the housing (3), or itself forms part of the housing (3).
32. 32. Inhaler component according to aspect 31, characterized by a reservoir (45) communicating with the capillary gap (41), which adjoins the liquid container (4) and is separated from it by the openable closure (18).
33. 33. Inhaler component according to aspect 32, characterized by a pin (46) which is mounted in an axially displaceable manner in the housing (3) and whose first end (47) is directed towards the openable closure (18) and whose second end (48) when the closure is closed ( 18) protrudes like an extension from the outer surface of the housing (3).
34. 34. Inhaler comprising an inhaler component according to aspect 33 and a reusable inhaler part (1) which can be coupled to the inhaler component (2), characterized in that the second end (48) of the pin is connected to the reusable inhaler part (1) during coupling is in a ram-like active connection.
35. 35. Inhaler component according to aspect 33, characterized in that the reservoir (45) communicates with the chamber (21) via a ventilation channel (52).
36. 36. The inhaler component according to aspect 30, characterized in that the liquid container (4) is arranged in the housing (3) so that it can be manually displaced along a displacement axis Y between two stop positions, and the liquid container (4) in the first stop position is provided with a non-releasable blocking device ( 73) interacts, and the liquid container (4) in the second stop position interacts with an opening means (81, 82) opening the openable closure (18).
37. 37. Inhaler component according to aspect 36, characterized in that the opening means (81, 82) comprises a first spike (81) which is formed by the capillary gap (41) and which penetrates the openable closure (18) in the second stop position, as a result of which the capillary coupling with the liquid material (16) is produced.
38. 38. Inhaler component according to aspect 37, characterized by a ventilation channel (52), the first end of which communicates with the chamber (21) and the second end of which is designed as a second spike (82) which closes the openable closure (18) in the second stop position penetrates.
39. 39. Inhaler component according to aspect 36, characterized in that the blocking device that cannot be unlocked consists of a projection (73) against which the liquid container (4) abuts in the first stop position.
40. 40. Inhaler component according to one of aspects 36-39, comprising a mouthpiece (5) with a mouthpiece channel (66) through which a user is presented with the vapour-air mixture and/or condensation aerosol, characterized in that the displacement axis Y is at least approximately parallel to the central axis of the mouthpiece channel (66), and the liquid container (4) protrudes with an end section laterally next to the mouthpiece (5) out of the housing (3) at least in the first stop position.
41. 41. Inhaler component according to one of aspects 27-33 and 35-40, characterized by a buffer reservoir (53) which communicates with the capillary gap (41) and itself consists of capillaries (54).
42. 42. Inhaler component according to aspect 23 with a liquid reservoir (84) consisting of an elastic, open-pored material and impregnated with the liquid material (16), characterized in that the composite (22, 39) is sandwiched between one of the two plate-shaped contacts (23) on the one hand, and the liquid reservoir (84) on the other hand is clamped, whereby the wick is capillary coupled to the liquid material (16) in the liquid reservoir (84).
43. 43. Inhaler component according to one of aspects 1-23 with a condensate binding device for receiving and storing condensate residues which are formed in the course of generating the vapour-air mixture and/or condensation aerosol, characterized in that the condensate binding device consists of an open-pored, absorbent body (57) which is spaced from but in close proximity to the capillary structure of the wick exposed in said portion.
44. 44. Inhaler component according to aspect 43, characterized in that the open-pored, absorbent body (57) directly covers the capillary structure of the wick that is exposed in said section.
45. 45. Inhaler component according to aspect 43 or 44, characterized in that the open-pored, absorbent body (57) comprises two parts or sections arranged at a distance from one another, and the composite (22, 39) is arranged at least in sections between the two parts or sections.
46. 46. Inhaler component according to one of aspects 43-45, characterized in that the open-pored, absorbent body (57) is arranged in the chamber (21) and fills out the majority of the chamber (21).
47. 47. Inhaler component according to one of aspects 43-46, characterized in that the open-pored, absorbent body (57) consists of a dimensionally stable material which largely retains its shape even after complete infiltration with the condensate residues.
48. 48. Inhaler component according to one of aspects 43-47, characterized in that the open-pored, absorbent body (57) is largely enclosed by the housing (3) and is inseparably connected to the housing (3).
49. 49. Inhaler component according to one of aspects 43-48, characterized by a two-stage condensate separating device, consisting firstly of the open-pore, absorbent body (57) and secondly of a cooler through which the vapor-air mixture formed and/or condensation aerosol can flow.
50. 50. Inhaler component according to aspect 49, characterized in that the cooler (61) is formed by a tobacco filling (61).
51. 51. Inhaler component according to aspect 50, characterized in that the volume of the tobacco filling (61) is greater than 3 cm3.
52. 52. Inhaler component according to one of aspects 1-23 with a mouthpiece (5) formed mouthpiece opening, which communicates with the chamber (21) and through which a user receives the vapor-air mixture and / or condensation aerosol presented, wherein during inhalation between the air inlet opening (26) and the mouthpiece opening, a flow forms in the direction of the mouthpiece opening, which flow passes through the assembly (22, 39) at least in sections, characterized in that downstream of the assembly (22, 39) there is at least one air bypass opening (68) is arranged, through which additional air from the environment is fed into the flow, and the effective flow cross-section of the air bypass opening (68) is at least 0.5 cm2.
53. 53. Inhaler component according to aspect 52, characterized in that the air bypass opening consists of two bypass openings (68) which are arranged in opposite housing sections.
54. 54. Inhaler component according to aspect 53, characterized in that two guide vanes (69) are connected to the two bypass openings (68), which point in the direction of the mouthpiece opening and strive towards one another, and the free ends of which form a nozzle-shaped orifice opening (71) through which the vapor-air mixture formed and/or condensation aerosol flows out of the chamber (21) and then mixes with the air flowing in from the bypass openings (68).
55. 55. Inhaler component according to aspect 52, characterized in that a flow homogenizer (72) is arranged downstream of the air bypass opening (68), the flow resistance of which is less than 1 mbar at an air throughput of 250 mL/sec.
56. 56. Inhaler component according to one of aspects 1-23, characterized by a plurality of composites (39a, 39b, 39c) with different heat capacities arranged next to one another.
57. 57. Inhaler component according to one of aspects 1-23, characterized by a plurality of composites (39a, 39b, 39c) arranged next to one another and having different heating element properties.
58. 58. Inhaler component according to one of aspects 1-23, characterized by a plurality of assemblies arranged next to one another with electrical heating elements which can be controlled in different ways.
59. 59. Inhaler component according to one of aspects 1-23, characterized in that several composites arranged next to one another are provided, and liquid materials with different compositions are assigned to the composites for evaporation.
60. 60. Inhaler component according to one of aspects 1-23 with a plurality of assemblies (22a, 22b) arranged next to one another, the heating elements of which consist of electrical heating resistors, characterized in that the heating resistors are connected to one another in series.
61. 61. An inhaler comprising an inhaler component (2) according to any one of aspects 1-33 and 35-60.

Claims (11)

Inhaler component for the intermittent and inhalation or train-synchronous formation of a vapor-air mixture and/or condensation aerosol, comprising: a housing (3); a chamber (21) arranged in the housing (3); an air inlet port (26) for admitting air from the environment into the chamber (21); an electrical heating element for evaporating a portion of a liquid material (16), the vapor formed mixing in the chamber (21) with the air supplied through the air inlet opening (26) and forming the vapour/air mixture and/or condensation aerosol ; and a wick with a capillary structure, which wick forms a composite (22) with the heating element and automatically supplies the heating element again with the fresh liquid material (16) after evaporation, characterized in that the composite (22) is a planar structure comprising an electrically non-conductive material arranged on a metal foil. The inhaler component of claim 1, wherein the electrically non-conductive material is fused silica. The inhaler component of claim 1 or claim 2, wherein the wick is foraminous through the thickness. The inhaler component of claim 3, wherein the perforation is performed by a laser. The inhaler component of any one of claims 1 to 4, wherein the composite (22) has at least two layers. The inhaler component of claim 5, wherein the layers include at least one of the following structures: plate, foil (31), paper, cloth (32), open cell fibrous structure (33), open cell sintered structure (34), open cell foam (37), and open cell deposition structure. Inhaler component according to Claim 6, characterized in that the layers are connected to one another by a heat treatment. Inhaler component according to one of Claims 1 to 7, in which the composite (22, 39) penetrates the chamber (21) in the manner of a bridge and is attached with two end sections to two electrically conductive, plate-shaped contacts (23), and the heating element with the contacts (23) is electrically contacted. Inhaler component according to claim 8, wherein the electrical contacting of the heating element consists of a welded or sintered connection. Inhaler component according to Claim 8, characterized in that the electrical contacting of the heating element consists of an adhesive connection using an electrically conductive adhesive. An inhaler comprising an inhaler component (2) according to any one of claims 1 to 10.

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